Organic light-emitting diodes and methods for assembly and enhanced charge injection

ABSTRACT

New organic light-emitting diodes and related electroluminescent devices and methods for fabrication, using siloxane self-assembly techniques.

This application is a continuation-in-part of and claims priority benefit from application Ser. No. 09/187,891, filed on Nov. 6, 1998, which is a continuation-in-part of application Ser. No. 08/673,600, filed on Jun. 25, 1996, and issued as U.S. Pat. No. 5,834,100, each of which are incorporated herein by reference in their entirety.

The United States Government has certain rights to this invention pursuant to Grant Nos. N0014-95-1-1319 and DMR-00769097 from the Office of Naval Research and National Science Foundation, respectively, to Northwestern University.

BACKGROUND OF THE INVENTION

This invention relates generally to organic electroluminescent devices with organic films between anodic and cathodic electrodes, and more particularly to such devices and methods for their assembly using the condensation of various silicon moieties.

Organic electroluminescent devices have been known, in various degrees of sophistication, since the early 1970's. Throughout their development and consistent with their function and mode of operation, they can be described generally by way of their physical construction. Such devices are characterized generally by two electrodes which are separated by a series of layered organic films that emit light when an electric potential is applied across the two electrodes. A typical device can consist, in sequence, of an anode, an organic hole injection layer, an organic hole transport layer, an organic electron transport layer, and a cathode. Holes are generated at a transparent electrode, such as one constructed of indium-tin-oxide, and transported through a hole-injecting or hole-transporting layer to an interface with an electron-transporting or electron-injecting layer which transports electrons from a metal electrode. An emissive layer can also be incorporated at the interface between the hole-transporting layer and the electron-transporting layer to improve emission efficiency and to modify the color of the emitted light.

Significant progress has been made in the design and construction of polymer- and molecule-based electroluminescent devices, for light-emitting diodes, displays and the like. Other structures have been explored and include the designated “DH” structure which does not include the hole injection layer, the “SH-A” structure which does not include the hole injection layer or the electron transport layer, and the “SH-B” structure which does not include the hole injection layer or the hole transport layer. See, U.S. Pat. No. 5,457,357 and in particular col. 1 thereof, which is incorporated herein by reference in its entirety.

The search for an efficient, effective electroluminescent device and/or method for its production has been an ongoing concern. Several approaches have been used with certain success. However, the prior art has associated with it a number of significant problems and deficiencies. Most are related to the devices and the methods by which they are constructed, and result from the polymeric and/or molecular components and assembly techniques used therewith.

The fabrication of polymer-based electroluminescent devices employs spin coating techniques to apply the layers used for the device. This approach is limited by the inherently poor control of the layer thickness in polymer spin coating, diffusion between the layers, pinholes in the layers, and inability to produce thin layers which leads to poor light collection efficiency and the necessity of high D.C. driving voltages. The types of useful polymers, typically poly(phenylenevinylenes), are greatly limited and most are environmentally unstable over prolonged use periods.

The molecule-based approach uses vapor deposition techniques to put down thin films of volatile molecules. It offers the potential of a wide choice of possible building blocks, for tailoring emissive and other characteristics, and reasonably precise layer thickness control. Impressive advances have recently been achieved in molecular building blocks—especially in electron transporters and emitters, layer structure design (three versus two layers), and light collection/transmission structures (microcavities).

Nevertheless, further advances must be made before these devices are optimum. Component layers which are thinner than achievable by organic vapor deposition techniques would allow lower DC driving voltages and better light transmission collection characteristics. Many of the desirable component molecules are nonvolatile or poorly volatile, with the latter requiring expensive, high vacuum or MBE growth equipment. Such line-of-site growth techniques also have limitation in terms of conformal coverage. Furthermore, many of the desirable molecular components do not form smooth, pinhole-free, transparent films under these conditions nor do they form epitaxial/quasiepitaxial multilayers having abrupt interfaces. Finally, the mechanical stability of molecule-based films can be problematic, especially for large-area applications or on flexible backings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A and 1B show structural formulae for porphyrinic compounds which are illustrative examples of compounds of the type which can be used as hole injection components/agents in the preparation of the molecular conductive or hole injection layers and electroluminescent media of this invention. In FIG. 1, M is Cu, Zn, SiCl₂, or 2H; Q is N or C(X), where X is a substituted or unsubstituted alkyl or aryl group; and R is H, trichlorosilyl, trialkoxysilyl, or a moiety having 1 to 6 carbon atoms which can include trichlorosilyl or trialkoxysilyl groups, substituted on the C₁-C₄, C₈-C₁₁, C₁₅-C₁₈ and/or C₂₂-C₂₅ positions. In FIG. B, M is Cu, Zn, SiCl₂, or 2H; Q is N or C(X), where X is a substituted or unsubstituted alkyl or aryl group; and T₁/T₂ is H, trichlorosilyl, trialkoxysilyl, or a moiety having 1 to 6 carbon atoms which can include trichlorosilyl or trialkoxysilyl groups.

FIGS. 2A-2C show structural formulae for arylamine compounds which are illustrative examples of compounds of the type which can be used as hole transport compounds/agents in the preparation of the molecular conductive or hole transport layers and electroluminescent media of this invention. In FIG. 2A, R₂, R₃ and/or R₄ can be H, trihalosilyl, trialkoxysilyl, dihalosilyl, dialkoxysilyl, or a moiety having 1 to 6 carbon atoms which can include dialkyldichlorosilyl, dialkyldialkoxysilyl, trichlorosilyl or trialkoxysilyl groups substituted anywhere on the aryl positions. In FIG. 2B, Q₁ and Q₂ can be substituted or unsubstituted tertiary aryl amines, such as those described with FIG. 2A; and G is a linking group to include but not limited to an alkyl, aryl, cylcohexyl or heteroatom group. In FIG. 2C, Ar is an arylene group; n is the number of arylene groups from 1-4; and R₅, R₆, R₇, and/or R₈ can be H, trihalosilyl, trialkoxysilyl, dihalosilyl, dialkoxysilyl or a moiety having 1 to 6 carbon atoms which can include dialkyldichlorosilyl, dialkyldialkoxysilyl, trichlorosilyl or trialkoxysilyl groups substituted anywhere on the aryl positions.

FIGS. 3A-3C show structural formulae for aryl compounds which are illustrative of examples of compounds of the type which can be used as emissive compounds/agents in the preparation of the molecular conductive layers and electroluminescent media of this invention. In FIG. 3A, R₉ and R₁₀ can be H, trihalosilyl, trialkoxysilyl, dihalosilyl, dialkoxysilyl, or a moiety having 1 to 6 carbon atoms which can include dialkyldichlorosilyl, dialkyldialkoxysilyl, trichlorosilyl or trialkoxysilyl groups substituted anywhere on the aryl positions. In FIG. 3B, M is Al or Ga; and R₁₁-R₁₄ can be H, trihalosilyl, trialkoxysilyl, dihalosilyl, dialkoxysilyl, or a moiety having 1 to 6 carbon atoms which can include dialkyldichlorosilyl, dialkyldialkoxysilyl, trichlorosilyl or trialkoxysilyl groups substituted anywhere on the aryl positions. In FIG. 3C, Ar is arylene; and R₁₅-R₁₈ can be H, trihalosilyl, trialkoxysilyl, dihalosilyl, dialkoxysilyl, or a moiety having 1 to 6 carbon atoms which can include dialkyldichlorosilyl, dialkyldialkoxysilyl, trichlorosilyl or trialkoxysilyl groups substituted anywhere on the aryl positions.

FIGS. 4A-4C show structural formulae for heterocyclic compounds which are illustrative examples of compounds of the type which can be used as electron transport components/agents in the preparation of the molecular conductive or electron transport layers and in electroluminescent media of this invention. In FIGS. 4A-4C, X is O or S; and R₁₉-R₂₄ can be aryl groups substituted with the following substituents anywhere on the aryl ring: trihalosilyl, trialkoxysilyl, dihalosilyl, dialkoxysilyl, or a moiety having 1 to 6 carbon atoms which can contain dialkyldichlorosilyl, dialkyldialkoxysilyl, trichlorosilyl or trialkoxysilyl groups.

FIGS. 5A and 5B (ITO is indium-tin-oxide; HTL is hole transport layer and ETL is electron transport layer) show, schematically and in a step-wise manner by way of illustrating the present invention, use of the components/agents of Examples 1-5 and FIGS. 1-4 in the self-assembly and preparation of an organic light-emitting diode device. In particular, the molecular representation FIG. 5A illustrates the hydrolysis of an assembled silicon/silane component/agent to provide an Si—OH functionality reactive toward a silicon/silane moiety of another component, agent or conductive layer. The block and molecular representations of FIG. 5B illustrate a completed assembly.

FIG. 6 shows an alternative synthetic sequence enroute to several arylamine components/agents, also in accordance with the present invention.

FIG. 7 shows, schematically and by way of illustrating an alternative embodiment of the present invention, use of the components/agents of FIG. 6 in the preparation of another representative electroluminescent device.

FIG. 8 graphically correlates x-ray reflectivity measurements of film thickness with the number of capping layers applied to a substrate. As calculated from the slope of the line (y=8.3184x), each layer is about 7.84 Å in dimensional thickness.

FIG. 9 graphically shows cyclic voltametry measurements, using 10⁻³M ferrocene in acetonitrile, taken after successive layer (c-e) deposition and as compared to a bare ITO electrode (a). Even one capping layer (b), in accordance with this invention, effectively blocks the electrode surface. Complete blocking is observed after deposition of three or four layers. The sweep rate was 100 mV/sec, and the electrode area was about 0.7 cm².

FIGS. 10A-C graphically illustrate various utilities and/or performance characteristics (current density, quantum efficiency and forward light output, respectively, versus voltage) achievable through use of the present invention, as a function of the number of capping layers on an electrode surface. 0 layers, bare ITO (⋄), 1 layer, 8 Å (□), 2 layers, 17 Å (●), 3 layers, 25 Å (▴) and 4 layers, 33 Å (∇). Reference is made to example 10.

FIG. 11A shows molecular structures of hole adhesion/injection molecular components: TAA (shown after crossliiking), TPD-Si₂ (shown after crosslinking), and prior art copper phthalocyanine, Cu(Pc). FIG. 11B illustrates one possible scheme for the synthesis of a preferred TPD-Si₂ adhesion/injection interlayer molecular precursor. Reference is also made to the procedures described in Example 2.

FIGS. 12A-D provide optical microscopic images of vapor-deposited TPD film (100 nm) morphology after annealing at 80° C. for 1.0 h on ITO substrates coated with a cured 40 nm thick TPD-Si₂ film (12A) and on bare ITO (12B); polarized optical image of TPD film (100 nm) morphology before (12C) and after (12D) annealing the bilayer structure: ITO/CuPc(10 nm)/TPD (100 nm) at 80° C. for 0.50 h.

FIGS. 13A-C show, in turn, (A) light output, (B) external quantum efficiency, and (C) current-voltage characteristics as a function of operating voltage for OLED devices having the structure: ITO/(adhesion/injection/molecular component interlayer)/TPD hole transport layer (50 nm)/Alq (60 nm)/Al, where the injection/adhesion component interlayer is prior art Cu(Pc) (10 nm), TAA (15 nm), and TPD-Si₂ (40 nm).

FIG. 14 compares injection characteristics of hole-only devices having the structure ITO/molecular component interlayer/TPD (250 nm)/ Au(5 nm)/Al (180 nm) for various anode functionalization layers.

FIG. 15 graphically illustrates by comparison the effect of thermal stressing (90° C. under vacuum) on device characteristics of ITO/(injection/adhesion interlayer)/TPD(50 nm)/Alq(60 nm)/Al (100 nm) devices, where the molecular component interlayer is TPD-Si₂ (40 nm), TAA (15 nm), and prior art CuPc (10 nm).

FIG. 16A provides the chemical structure of the TPD-Si₂ precursor molecule and crosslinked TPD-Si₂ self-assembled monolayer; FIG. 16B provides electroluminescence spectrum of a PFO-based PLED device having the structure ITO/TPD-Si₂ SAM or PEDOT-PSS HIL/PFO/Ca/Al. The inset shows the molecular structure of PFO.

FIGS. 17A-C show, respectively, light output, current efficiency and current-voltage characteristics as a function of operating voltage for PLED devices having the structure: ITO/SAM or HTL/PFO/Ca/Al. ▴ TPO-Si₂SAM, □ PEDOT-PSS HTL, ● Bare ITO.

FIG. 18 provides a graphic comparison of the injection characteristics of hole-only devices having the structure ITO/SAM or HTL/PFO/Au/Al. ▴ TPD-Si₂SAM, □ PEDOT-PSS HTL, ● Bare ITO.

FIG. 19 plots energy level alignment of blue PLED devices with different anode modification structures. The IP of TPD-Si₂ SAM modified ITO was determined by ultraviolet photoelectron spectroscopy.

FIG. 20 provides structures of several light emissive polymers, representative of other known and available compositions useful for emission at wavelengths across the visible spectrum, such emission as can be enhanced in accordance with this invention. Reference is made to example 32.

SUMMARY OF THE INVENTION

In light of the foregoing, it is an object of the present invention to provide electroluminescent articles and/or devices and method(s) for their production and/or assembly, thereby overcoming various deficiencies and shortcomings of the prior art, including those outlined above. It will be understood by those skilled in the art that one or more aspects of this invention can meet certain objectives, while one or more other aspects can meet certain other objectives. Each objective may not apply equally, in all its respects, to every aspect of this invention. As such, the following objects can be viewed the alternative with respect to any one aspect of this invention.

It is an object of the present invention to provide control over the thickness dimension of a luminescent medium and/or the conductive layers of such a medium, to control the wavelength of light emitted from any electroluminescent device and enhance the efficiency of such emission.

It can be another object of the present invention to provide molecular components for the construction and/or modification of an electroluminescent medium and/or the conductive layers thereof, which will allow lower driving and/or turn-on voltages than are available through use of conventional materials.

It can also be an object of the present invention to provide component molecules which can be used effectively in liquid media without resort to high vacuum or MBE growth equipment.

It can also be an object of the present invention to provide conformal conductive layers and the molecular components thereof which allows for the smooth, uniform deposition on an electrode, substrate surface and/or previously-deposited layers.

It can also be an object of this invention to provide an electroluminescent medium having a hybrid structure and where one or more of the layers is applied by a spin-coat or vapor deposition technique to one or more self-assembled conductive layers.

Other objects, features and advantages of the present invention will be apparent from this summary of the invention and its descriptions of various preferred embodiments, and will be readily apparent to those skilled in the art having knowledge of various electroluminescent devices and assembly/production techniques. Such objects, features, benefits and advantages will be apparent from the above as taken into conjunction with the accompanying examples, data, figures and all reasonable inferences to be drawn therefrom, alone or with consideration of the references incorporated herein.

This invention describes, in part, a new route to the fabrication of light-emitting organic multilayer heterojunction devices, useful for both large and small, multicolored display applications. As described more fully below, electron and hole transporting layers, as well as the emissive layer, as well as any other additional layers, are applied, developed and/or modified by molecular self-assembly techniques. As such, the invention can provide precise control over the thickness of a luminescent medium or the conductive layers which make up such a medium, as well as provide maximum light generation efficiency. Use of the present invention provides strong covalent bonds between the constituent molecular components, such that the mechanical, thermal, chemical and/or photochemical stability of such media and/or conductive layers, as can be used with an electroluminescent device, are enhanced. The use of such components also promotes conformal surface coverage to prevent cracks and pinhole deformities.

More specifically, the siloxane self-assembly techniques described herein allow for the construction of molecule-based electroluminescent media and devices. As described more fully below, various molecular components can be utilized to control the thickness dimension of the luminescent media and/or conductive layers. Nanometer dimensions can be obtained, with self-sealing, conformal coverage. The resulting covalent, hydrophobic siloxane network imparts considerable mechanical strength, as well as enhancing the resistance of such media and/or devices to dielectric breakdown, moisture intrusion, and other degradative processes.

In part, the present invention is an electroluminescent article or device which includes (1) an anode, (2) a plurality of molecular conductive layers where one of the layers is coupled to the anode with silicon-oxygen bonds and each of the layers is coupled one to another with silicon-oxygen bonds, and (3) a cathode in the electrical contact with the conductive layers. More generally and within the scope of this invention, an anode is separated from a cathode by an organic luminescent medium. The anode and the cathode are connected to an external power source by conductors. The power source can be a continuous direct, alternating or an intermittent current voltage source. A convenient conventional power source, including any desired switching circuitry, which is capable of positively biasing the anode with respect to the cathode, can be employed. Either the anode or cathode can be at ground potential.

The conductive layers can include but are limited to a hole transport layer, a hole injection layer, an electron transport layer and an emissive layer. Under forward biasing conditions, the anode is at a higher potential than the cathode, and the anode injects holes (positive charge carriers) into the conductive layers and/or luminescent medium while the cathode injects electrons therein. The portion of the layers/medium adjacent to the anode forms a hole injecting and/or transporting zone while the portion of the layers/medium adjacent to the cathode forms an electron injecting and/or transporting zone. The injected holes and electrons each migrate toward the oppositely charged electrode, resulting in hole-electron interaction within the organic luminescent medium of conductive layers. A migrating electron drops from its conduction potential to a valence band in filing a hole to release energy as light. In such a manner, the organic luminescent layers/medium between the electrodes performs as a luminescent zone receiving mobile charge carriers from each electrode. Depending upon the construction of the article/device, the released light can be emitted from the luminescent conductive layers/medium through one or more of edges separating the electrodes, through the anode, through the cathode, or through any combination thereof. See, U.S. Pat. No. 5,409,783 and, in particular cols. 4-6 and FIG. 1 thereof, which is incorporated herein by reference in its entirety. As would be understood by those skilled in the art, reverse biasing of the electrodes will reverse the direction of mobile charge migration, interrupt charge injection, and terminate light emission. Consistent with the prior art, the present invention contemplates a forward biasing DC power source and reliance on external current interruption or modulation to regulate light emission.

As demonstrated and explained below, it is possible to maintain a current density compatible with efficient light emission while employing a relatively low voltage across the electrodes by limiting the total thickness of the organic luminescent medium to nanometer dimensions. At the molecular dimensions possible through use of this invention, an applied voltage of less than about 10 volts is sufficient for efficient light emission. As discussed more thoroughly herein, the thickness of the organic luminescent conductive layers/medium can be designed to control and/or determine the wavelength of emitted light, as well as reduce the applied voltage and/or increase in the field potential.

Given the nanometer dimensions of the organic luminescent layers/medium, light is usually emitted through one of the two electrodes. The electrode can be formed as a translucent or transparent coating, either on the organic layer/medium or on a separate translucent or transparent support. The layer/medium thickness is constructed to balance light transmission (or extinction) and electrical conductance (or resistance). Other considerations relating to the design, construction and/or structure of such articles or devices are as provided in the above referenced U.S. Pat. No. 5,409,783, such considerations as would be modified in accordance with the molecular conductive layers and assembly methods of the present invention.

In preferred embodiments, the conductive layers have molecular components, and each molecular component has at least two silicon moieties. In highly preferred embodiments, each silicon moiety is a halogenated or alkoxylated silane and silicon-oxygen bonds are obtainable from the condensation of the silane moieties with hydroxy functionalities. In preferred embodiments, the present invention employs an anode with a substrate having a hydroxylated surface portion. The surface portion is transparent to near-IR and visible wavelengths of light. In such highly preferred embodiments the hydroxylated surface portions include SiO₂, In₂.xSnO₂, Ge and Si, among other such materials.

In conjunction with anodes and the hydroxylated surface portions thereof, the conductive layers include molecular components, and each molecular component has at least two silicon moieties. As discussed above, in such embodiments, each silicon moiety is a halogenated or alkoxylated silane, and silicon-oxygen bonds are obtainable from the condensation of the silane moieties with hydroxy functionalities which can be on a surface portion of an anode. Consistent with such preferred embodiments, a cathode is in electrical contact with the conductive layers. In highly preferred embodiments, the cathode is vapor deposited on the conductive layers, and constructed of a material including Al, Mg, Ag, Au, In, Ca and alloys thereof.

In part, the present invention is a method of producing a light-emitting diode having enhanced stability and light generation efficiency. The method includes (1) providing an anode with a hydroxylated surface; (2) coupling the surface to a hole transport layer having a plurality of molecular components, with each component having at least two silicon moieties reactive with the surface, with coupling of one of the silicon moieties to form silicon-oxygen bonds between the surface and the hole transport layer; (3) coupling the hole transport layer to an electron transport layer, the electron transport layer having a plurality of molecular components with each of the components having at least two silicon moieties reactive with the hole transport layer, with the coupling of one of the silicon moieties to form silicon-oxygen bonds between the hole and electron transport layers; and (4) contacting the electron transport layer with a cathode material.

In preferred embodiments of this method, the hole transport layer includes a hole injecting zone of molecular components and a hole transporting zone of molecular components. Likewise, in preferred embodiments, each silicon moiety is a halogenated or alkoxylated silane such that, with respect to this embodiment, coupling the hole transport layer to the electron transport layer further includes hydrolyzing the halogenated or alkoxylated silane. Likewise, with respect to a halogenated or alkoxylated silane embodiment, contacting the electron transport layer with the cathode further includes hydrolyzing the silane.

In part, the present invention is a method of controlling the wavelength of light emitted from an electroluminescent device. The inventive method includes (1) providing in sequence a hole transport layer, an emissive layer and an electron transport layer to form a medium of organic luminescent layers; and (2) modifying the thickness dimension of at least one of the layers, each of the layers including molecular components corresponding to the layer and having at least two silicon moieties reactive to a hydroxy functionality and the layers coupled one to another by Si—O bonds, the modification by reaction of the corresponding molecular components one to another to form Si—O bonds between the molecular components, and the modification in sequence of the provision of the layers.

In preferred embodiments of this inventive method, at least one silicon moiety is unreacted after reaction with a hydroxy functionality. In highly preferred embodiments, modification then includes hydrolyzing the unreacted silicon moiety of one of the molecular components to form a hydroxysilyl functionality and condensing the hydroxysilyl functionality with a silicon moiety of another molecular component to form a siloxane bond sequence between the molecular components.

In highly preferred embodiments, the silicon moieties are halogenated or alkoxylated silane moieties. Such embodiments include modifying the thickness dimension by hydrolyzing the unreacted silane moiety of one of the molecular components to form a hydroxysilyl functionality and condensing the hydroxysilyl functionality with a silane moiety of another molecular component to form a siloxane bond sequence between the molecular components.

While the organic luminescent conductive layers/medium of this invention can be described as having a single organic hole injecting or transporting layer and a single electron injecting or transporting layer, modification of each of these layers with respect to dimensional thickness or into multiple layers, as more specifically described below, can result in further refinement or enhancement of device performance by way of the light emitted therefrom. When multiple electron injecting and transporting layers are present, the layer receiving holes is the layer in which hole-electron interaction occurs, thereby forming the luminescent or emissive layer of the device.

The articles/devices of this invention can emit light through either the cathode or the anode. Where emission is through the cathode, the anode need not be light transmissive. Transparent anodes can be formed of selected metal oxides or a combination of metal oxides having a suitably high work function. Preferred metal oxides have a work function of greater than 4 electron volts (eV). Suitable anode metal oxides can be chosen from among the high (>4 eV) work function materials. A transparent anode can also be formed of a transparent metal oxide layer on a support or as a separate foil or sheet.

The devices/articles of this invention can employ a cathode constructed of any metal, including any high or low work function metal, heretofore taught to be useful for this purpose and as further elaborated in that portion of the incorporated patent referenced in the preceding paragraph. As mentioned therein, fabrication, performance, and stability advantages can be realized by forming the cathode of a combination of a low work function (<4 eV) metal and at least one other metal. Available low work function metal choices for the cathode are listed in cols. 19-20 of the aforementioned incorporated patent, by periods of the Periodic Table of Elements and categorized into 0.5 eV work function groups. All work functions provided therein are from Sze, Physics of Semiconductor Devices, Wiley, New York, 1969, p.366.

A second metal can be included in the cathode to increase storage and operational stability. The second metal can be chosen from among any metal other than an alkali metal. The second metal can itself be a low work function metal and thus be chosen from the above-referenced list and having a work function of less than 4 eV. To the extent that the second metal exhibits a low work function it can, of course, supplement the first metal in facilitating electron injection.

Alternatively, the second metal can be chosen from any of the various metals having a work function greater than 4 eV. These metals include elements resistant to oxidation and, therefore, those more commonly fabricated as metallic elements. To the extent the second metal remains invariant in the article or device, it can contribute to the stability. Available higher work function (4 eV or greater) metal choices for the cathode are listed in lines 50-69 of col. 20 and lines 1-15 of col. 21 of the aforementioned incorporated patent, by periods of the Periodic Table of Elements and categorized into 0.5 eV work function groups.

As described more fully in U.S. Pat. No. 5,156,918 which is incorporated herein by reference in its entirety, the electrodes and/or substrates of this invention have, preferably, a surface with polar reactive groups, such as a hydroxyl (—OH) group. Materials suitable for use with or as electrodes and/or substrates for anchoring the conductive layers and luminescent media of this invention should conform to the following requirements: any solid material exposing a high energy (polar) surface to which layer-forming molecules can bind. These may include: metals, metal oxides such as SiO₂, TiO₂, MgO, and Al₂O₃ (sapphire), semiconductors, glasses, silica, quartz, salts, organic and inorganic polymers, organic and inorganic crystals and the like.

Inorganic oxides (in the form of crystals or thin films) are especially preferred because oxides yield satisfactory hydrophilic metal hydroxyl groups on the surface upon proper treatment. These hydroxyl groups react readily with a variety of silyl coupling reagents to introduce desired coupling functionalities that can in turn facilitate the introduction of other organic components.

The physical and chemical nature of the anode materials dictates specific cleaning procedures to improve the utility of this invention. Alkaline processes (NaOH aq.) are generally used. This process will generate a fresh hydroxylated surface layer on the substrates while the metal oxide bond on the surface is cleaved to form vicinal hydroxyl groups. High surface hydroxyl densities on the anode surface can be obtained by sonicating the substrates in an aqueous base bath. The hydroxyl groups on the surface will anchor and orient any of the molecular components/agents described herein. As described more fully below, molecules such as organosilanes with hydrophilic functional groups can orient to form the conductive layers.

Other considerations relating to the design, material choice and construction of electrodes and/or substrates useful with this invention are as provided in the above referenced and incorporated U.S. Pat. No. 5,409,783 and in particular cols. 21-23 thereof, such considerations as would be modified by those skilled in the art in accordance with the molecular conductive layers, and assembly methods and objects of the present invention.

The conductive layers and/or organic luminescent medium of the devices/articles of this invention preferably contain at least two separate layers, at least one layer for transporting electrons injected from the cathode and at least one layer for transporting holes injected from the anode. As is more specifically taught in U.S. Pat. No. 4,720,432, incorporated herein by reference in its entirety, the latter is in turn preferably at least two layers, one in contact with the anode, providing a hole injecting zone and a layer between the hole injecting zone and the electron transport layer, providing a hole transporting zone. While several preferred embodiments of this invention are described as employing at least three separate organic layers, it will be appreciated that either the layer forming the hole injecting zone or the layer forming the hole transporting zone can be omitted and the remaining layer will perform both functions. However, enhanced initial and sustained performance levels of the articles or devices of this invention can be realized when separate hole injecting and hole transporting layers are used in combination.

Porphyrinic and phthalocyanic compounds of the type described in cols. 11-15 of the referenced/incorporated U.S. Pat. No. 5,409,783 can be used to form the hole injecting zone. In particular, the phthalocyanine structure shown in column 11 is representative, particularly where X can be, but is not limited to, an allyltrichlorosilane, alkyltrialkoxysilane, dialkyldialkoxysilane, or dialkyldichlorosilane functionality and where the alkyl and alkoxy groups can contain 1-6 carbon atoms or is hydrogen. Preferred porphyrinic compounds are represented by the structure shown in col. 14 and where R, T¹ and T² can be but are not limited to an alkyltrichlorosilane, alkyltrialkoxysilane, dialkyldialkoxysilane, or dialkyldichlorosilane functionality and where the alkyl and alkoxy groups contain 1-6 carbon atoms or is hydrogen. (See, also, FIGS. 1A and 1B, herein.) Preferred phthalocyanine- and porphyrin-based hole injection agents include silicon phthalocyanine dichloride and 5,10,15,20-tetraphenyl-21H,23H- porphine silicon (IV) dichloride, respectively.

The hole transporting layer is preferably one which contains at least one tertiary aromatic amine, examples of which are as described in FIGS. 2A-2C and Examples 1 and 2. Other exemplary arylamine core structures are illustrated in U.S. Pat. No. 3,180,730, which is incorporated herein by reference in its entirety, where the core structures are modified as described herein. Other suitable triarylamines substituted with a vinyl or vinylene radical and/or containing at least one active hydrogen containing group are disclosed in U.S. Pat. Nos. 5,409,783, 3,567,450 and 3,658,520. These patents are incorporated herein by reference in their entirety and the core structures disclosed are modified as described herein. In particular, with respect to the arylamines represented by structural formulas XX and XXIII in cols. 15-16 of U.S. Pat. No. 5,409,703, R²⁴, R²⁵, R²⁶, R²⁷, R³⁰, R³¹ and R³² can be an alkyltrichlorosilane, alkyltrialkoxysilane, dialkyldialkoxysilane, or dialkyldichlorosilane functionality where the alkyl and alkoxy groups can contain 1-6 carbon atoms or is hydrogen.

Molecular components of this invention comprising emissive agents and/or the emissive layer include those described herein in FIGS. 3A-3C and Example 5. Other such components/agents include various metal chelated oxinoid compounds, including chelates of oxine (also commonly referred to as 8-quinolinol or 8-hydroxyquinoline), such as those represented by structure III in col. 8 of the referenced and incorporated U.S. Pat. No. 5,409,783, and where Z² can be but is not limited to an allyltrichlorosilane, alkyltrialkoxysilane, dialkyldialkoxysilane, or dialkyldichlorosilane functionality and where the alkyl and alkoxy groups can contain 1-6 carbon atoms or is hydrogen. Other such molecular components/emissive agents include the quinolinolato compounds represented in cols. 7-8 of U.S. Pat. No. 5,151,629, also incorporated herein by reference in its entirety, where a ring substituent can be but is not limited to an alkyltrichlorosilane, alkyltrialkoxysilane, dialkyldialkoxysilane, or dialkyldichlorosilane functionality and where the alkyl and alkoxy groups can contain 1-6 carbon atoms or is hydrogen. In a similar fashion, the dimethylidene compounds of U.S. Pat. No. 5,130,603, also incorporated herein by reference in its entirety, can be used, as modified in accordance with this invention such that the aryl substituents can include an alkyltrichlorosilane, alkyltrialkoxysilane, dialkyldialkoxysilane, or dialkyldichlorosilane functionality and where the alkyl and alkoxy groups can contain 1-6 carbon atoms or is hydrogen.

Other components which can be used as emissive agents include without limitation anthracene, naphthalene, phenanthrene, pyrene, chrysene, perylene and other fused ring compounds, or as provided in col. 17 of the previously referenced and incorporated U.S. Pat. No. 5,409,783, such compounds as modified in accordance with this invention and as more fully described above. Modifiable components also include those described in U.S. Pat. Nos. 3,172,862, 3,173,050 and 3,710,167—all of which are incorporated herein by reference in their entirety.

Molecular components which can be utilized as electron injecting or electron transport agents and/or in conjunction with an electron injection or electron transport layer are as described in FIGS. 4A-4C and Examples 3(a)-(d) and 4. Other such components include oxadiazole compounds such as those shown in cols. 12-13 of U.S. Pat. No. 5,276,381, also incorporated herein by reference in its entirety, as such compounds would be modified in accordance with this invention such that the phenyl substituents thereof each include an alkyltrichlorosilane, alkyltrialkoxysilane, dialkyldialkoxysilane, or dialkyldichlorosilane functionality and where the alkyl and alkoxy groups can contain 1-6 carbon atoms or is hydrogen. Likewise, such components can be derived from the thiadiazole compounds described in U.S. Pat. No. 5,336,546 which is incorporated herein by reference in its entirety.

As described above, inorganic silicon moieties can be used in conjunction with the various molecular components, agents, conductive layers and/or capping layers. In particular, silane moieties can be used with good effect to impart mechanical, thermal, chemical and/or photochemical stability to the luminescent medium and/or device. Such moieties are especially useful in conjunction with the methodology described herein. Degradation is minimized until further synthetic modification is desired. Hydrolysis of an unreacted silicon/silane moiety provides an Si—OH functionality reactive with a silicon/silane moiety of another component, agent and/or conductive layer. Hydrolysis proceeds quickly in quantitative yield, as does a subsequent condensation reaction with an unreacted silicon/silane moiety of another component to provide a siloxane bond sequence between components, agents and/or conductive layers.

In general, the molecular agents/components in FIGS. 1-4 can be prepared with a lithium or Grignard reagent using synthetic techniques known to one skilled in the art and subsequent reaction with halosilane or alkoxysilane reagents. Alternatively, unsaturated olefinic or acetylenic groups can be appended from the core structures using known synthetic techniques. Subsequently, halosilane or alkoxysilane functional groups can be introduced using hydrosilation techniques, also known to one skilled in the art. Purification is carried out using procedures appropriate for the specific target molecule.

It has been observed previously that the performance characteristics of electroluminescent articles of the type described herein can be enhanced by the incorporation of a layer having a dielectric function between the anode and, for instance, a hole transport layer. Previous studies show that the vapor deposition of thin layers of LiF onto an anode before deposition of the other layer(s) improves performance in the areas of luminescence and quantum efficiency. However, this technique is limited in that the deposited LiF films are rough, degrade in air and do not form comformal, pinhole-free coatings.

The present invention is also directed to the application of self-assembly techniques to form layers which cap an electrode, provide dielectric and other functions and/or enhance performance relative to the prior art. Such capping layers are self-assembled films which are conformal in their coverage, can have dimensions less than one nanometer and can be deposited with a great deal of control over the total layer thickness. Accordingly, the present invention also includes an electroluminescent article or device which includes (1) an anode, (2) at least one molecular capping layer coupled to the anode with silicon-oxygen bonds, with each capping layer coupled one to another with silicon-oxygen bonds, (3) a plurality of molecular conductive layers, with one of the layers coupled to the capping layer with silicon-oxygen bonds and each conductive layer coupled one to another with silicon-oxygen bonds, and (4) a cathode in electric contact with a conductive layer. Likewise, and in accordance with this invention, the capping layer can be deposited on a conductive layer and/or otherwise introduced so as to be adjacent to a cathode, to enhance overall performance.

More generally and within the scope of this invention, the anode is separated from the cathode by an organic luminescent medium. The anode and cathode are connected to an external power source by conductors. The power source can be a continuous direct, alternating or intermittent current voltage source. A convenient conventional power source, including any desired switching circuitry, which is capable of positively biasing the anode with respect to the cathode, can be employed. Either the anode or cathode can be at ground potential.

In preferred embodiments, each conductive and/or capping layer has molecular components, and each molecular component has at least two silicon moieties. In highly preferred embodiments, each such conductive and/or capping component is a halogenated or alkoxylated silane, and silicon-oxygen bonds are obtainable from the condensation of the silane moieties with hydroxy functionalities. Without limitation, a preferred capping material is octachlorotrisiloxane. The anode and cathode can be chosen and/or constructed as otherwise described herein.

In part, the present invention is a method of using molecular dimension to control the forward light output of an electroluminescent device. The inventive method includes (1) providing an electrode and a molecular layer thereon, the layer coupled to the electrode with first molecular components having at least two silicon moieties reactive to a hydroxy functionality; and (2) modifying the thickness of the layer by reacting the molecular components with second components to form a siloxane bond sequence between the first and second molecular components, the second molecular components having at least two silicon moieties also reactive to a hydroxy functionality.

In preferred embodiments of this inventive method, at least one silicon moiety is unreacted after reaction with a hydroxy functionality. In highly preferred embodiments, the modification further includes hydrolyzing an unreacted silicon moiety of one of the molecular components to form a hydroxysilyl functionality and condensing the hydroxysilyl functionality with a silicon moiety of a third molecular component to form a siloxane bond sequence between the second and third molecular components. In highly preferred embodiments, the silicon moieties are halogenated or alkoxylated silane moieties.

In part, the present invention also includes any electroluminescent article for generating light upon application of an electrical potential across two electrodes. Such an article includes an electrode having a surface portion and a molecular layer coupled and/or capped thereon. The layer includes molecular components, and each component has at least two silicon moieties. The layer is coupled to the electrode with silicon-oxygen bonds. In preferred embodiments, each silicon moiety is a halogenated silane, and silicon-oxygen bonds are obtained from a condensation reaction. Likewise, and without limitation, the electrode has a substrate with a hydroxylated surface portion transparent to near-IR and visible wavelengths of light. Such a layer can be utilized to cap the electrode and/or enhance performance as otherwise described herein. More generally, in such an article or any other described herein, the luminescent medium can be constructed using either the self-assembly techniques described herein or the materials and techniques of the prior art.

The electroluminescent devices and related methods of this invention can demonstrate various interlayer/interfacial phenomena through choice of layer/molecular components and design of the resulting electroluminescent medium. As a point of reference, a number of cathode and anode interfacial structures can enhance charge injection, hence device performance. For instance, with vapor-deposited, anode/TPD (N-NM-diphenyl-N-N′-bis(3-methylphenyl)-(1-1′-biphenyl)-4-4′-diamine)/Alq (tris(quinoxalinato)Al(III))/cathode devices of the prior art, a dramatic increase in light output and quantum efficiency occurs when Å-scale LiF or CsF layers are interposed between the cathode and electron transport layer (ETL). Such thin dielectric layers are thought to lower the Al work function, thus reducing the effective electron injection barrier (energy level offset between the Alq LUMO and the Al Fermi level).

In contrast, modification of the ITO anode—hole transport layer (HTL) or emissive layer (EL) interface is somewhat more controllable, although similar mechanistic uncertainties pertain. Thus, a variety of ITO functionalization approaches produce phenomenologically similar effects, although less dramatic than those observed for the interposition of alkali fluoride at Al cathodes. These approaches include deposition onto ITO of nanoscale layers of various organic acids, copper phthalocyanine, or thicker (30-100 nm) layers of polyaniline or polythiophene (PEDOT), all resulting in somewhat enhanced luminous performance. Explanations for these phenomena are diverse, ranging from altering interfacial electric fields, balancing electron/hole injection fluence, confining electrons in the emissive layer, reducing injected charge back-scattering, and moderating anode Fermi level-HTL HOMO energetic discontinuities. This diversity of proposed mechanisms accurately reflects the complexity of interactions at OLED interfaces and, in many cases, the lack of necessary microstructural information.

In a departure from the prior art, the present invention can be considered in the context of one or more structural relationships between an OLED anode and/or its associated organic layers. Without restriction to any one theory or mode of operation, moderation of the surface energy mismatch can be effected at a hydrophilic oxide anode-hydrophobic HTL or EL interface, as demonstrated below using nanoscopic self-assembled silyl group functionalized amine components (see, for example, FIG. 11A and 1-4 TAA layers; 11 Å/layer). Promoting anode/ITO-HTL physical cohesion significantly enhances luminous performance and durability. Furthermore, as relates to another aspect of this invention, a silyl-group functionalized, crosslinkable amine layer having the core amine structure of the HTL component, TPD, (TPD-Si₂, FIG. 11A) significantly improves ITO/TPD/Alq/Al device performance and thermal durability (one metric of device stability) to an extent surprising, unexpected and unattainable with other anode functionalization structures. In contrast thereto, the commonly used copper phthalocyanine (Cu(Pc); FIG. 11A) anode functionalization layer actually templates crystallization of overlying TPD films at modest temperatures (Example 13 and FIG. 12D), consistent with the thermal instability of many Cu(Pc)-buffered OLED devices of the prior art.

Accordingly, in certain respects, the present invention contemplates a method of using an amine molecular component to enhance hole injection across the electrode-organic interface of a light emitting diode device. The inventive method includes (1) providing an anode; and (2) incorporating an electroluminescent medium adjacent the anode, the medium including but not limited to a molecular layer, coupled to the anode, of amine molecular components substituted with at least one silyl group, and thereon a hole transport layer of molecular components having the amine structure of the aforementioned molecular layer components. The molecular layer can have at least one of an arylamine component and an arylalkylamine component, including but not limited to those monoarylamine, diarylamine and triarylamine components described in the aforementioned and incorporated U.S. Pat. No. 5,409,783, modified and/or silyl-functionalized as provided herein. Other suitable arylamine and/or arylalkylamine structures are disclosed in U.S. Pat. Nos. 3,180,730, 3,567,450 and 3,658,520, each of which is incorporated herein in its entirety, such structures as can also be modified to provide silyl-functionality in accordance herewith. Likewise, a combination of such silyl-substituted components can be employed with beneficial effect.

In preferred embodiments of this inventive method, the aforementioned amine molecular layer components are alkylsilyl-substituted compounds of the type illustrated in FIGS. 2A and 2C. In highly preferred embodiments, such components include the alkylsilyl-substituted TAA and alkylsilyl substituted TPD compounds prepared as described herein. Regardless, such a molecular layer can be spin-coated on the anode surface or self-assembled, as described more fully above, to provide silicon-oxygen bonds therewith. A plurality of such molecular layers can be coupled successively on an anode surface—each layer coupled one to another with silicon-oxygen bonds—to improve structural stability and enhance device performance. As described herein and with reference to several of the following examples, hole injection can be enhanced by choice of a molecular layer with components having a structural relationship with those arylamine or arylalkylamine components of the hole transport layer. In preferred embodiments, such enhancement can be achieved through use of a silyl-functionalized TPD layer in conjunction with a TPD hole transport layer.

As such, in certain embodiments the present invention also includes an organic electroluminescent device for generating light upon application of an electrical potential across two electrodes. Such a device includes (1) an anode; (2) at least one molecular layer, coupled to the anode, of one or more of the aforementioned amine molecular components substituted with at least one silyl group; (3) a conductive layer of molecular components having the amine structure; and (4) a cathode in electrical contact with the anode. A preferred conductive layer includes a hole transport layer comprising components of the prior art incorporated herein by reference, or modified as described above. Preferred molecular layer components are alkylsilyl-substituted compounds of the type illustrated in FIGS. 2A and 2C, in particular silyl-functionalized TAA and TPD. In light of the aforementioned structural relationships and associated methodologies, a preferred conductive layer of such a device is a TPD hole transport layer, such a layer substantially without crystallization upon annealing and/or at device operation temperatures when used in conjunction with a molecular layer of components having the same or a structurally similar amine structure.

For structures utilizing an HTL component, as demonstrated herein, hydrophobic amine HTL—hydrophilic anode integrity is a factor in OLED performance; poor physical cohesion contributes to inefficient hole injection and ultimately, device failure. Enhanced performance can be achieved through use of molecular layer structures which maximize interfacial cohesion and charge transport. With reference to one preferred embodiment, a conveniently applied, spincoated silyl (Si) functionalized TPD analogue, TPD-Si₂ (FIGS. 11A-B), structurally similar to the overlying HTL, hence well-suited to stabilizing the interface, undergoes rapid crosslinking upon spincoating from solution and subsequent thermal curing to form a dense, robust siloxane matrix with imbedded TPD hole-transport components. The thickness of these layers (˜40 nm) was determined by specular X-ray reflectivity on samples deposited via identical techniques on single-crystal silicon. The RMS roughness of the TPD-Si₂ molecular layer films on ITO substrates of 30 Å RMS roughness is 8-12 Å by contact mode AFM. Crosslinked TPD-Si₂ films exhibit high thermal stability, with only 5% weight loss observed up to 400° C. by TGA, indicating substantial resistance to thermal degradation. Furthermore, cyclic voltammetry of 40 nm TPD-Si₂ films on ITO electrodes indicates that they support facile hole transport and are electrochemically stable.

The densely crosslinked nature of TPD-Si₂ molecular layer films is evident in the relatively large separation of oxidative and reductive peaks (200 mV), suggesting kinetically hindered oxidation/reduction processes with retarded counterion mobility. P. E. Smolenyak, E. J. Osburn, S.-Y. Chen, L.-K. Chau, D. F. O'Brian, N. R. Armstrong, Langmuir 1997,21, 6568. That TPD-Si₂ film coverage on ITO is conformal and largely pinhole-free is supported by studies using a previously described ferrocene probe technique. W. Li, Q. Wang, J. Cui, H. Chou, T. J. Marks, G. E. Jabbour, S. E. Shaheen, B. Kippelen, N. Pegyhambarian, P. Dutta, A. J. Richter, J. Anderson, P. Lee, N. Armstrong, Adv. Mater. 1999, 11, 730. The lack of significant current flow near the formal potential for ferrocene oxidation at a TPD-Si₂-coated ITO working electrode indicates suppression of ferrocene oxidation, consistent with largely pinhole-free surface coverage. G. Inzelt, Electroanalytical Chemistry, Vol. 18, Marcel Dekcker, New York, 1994, p. 89.

Several of the aforementioned considerations can also relate to polymer electroluminescence. While high brightness and high quantum efficiency polymer light-emitting diodes (PLEDs) can now be readily achieved in the red and green spectral regions, there are relatively few reports of efficient blue PLEDs. It is generally accepted in the art that hole injection is a factor limiting blue PLED device performance due to the high ionization potentials of most blue-emitting polymers, and that a hole transport layer is necessary in blue PLED structures to achieve acceptable performance. See, Y. Yang, Q. Pei, A. J. Heeger, J. Appl. Phys. 1996, 79, 934-939; A. W. Grice, D. D. C. Bradley, M. T. Bernius, M. Inbasekaran, W. W. Wu, E. P. Woo, Appl. Phys. Lett. 1998, 73, 629-631; W. Yu, J. Pei, Y. Cao, W. Huang, J. Appl. Phys. 2001, 89, 2343. Å common approach is the introduction, between an anode and an emissive polymer, of spin-coated, p-doped conductive polymer layers (thickness ˜40-60 nm) such as poly(3,4-ethylenedioxythiophene)-poly(styrenesulfonate) (PEDOT-PSS), polyaniline-camphorsulfonic acid (PANI-CSA), or polypyrrole-dodecylbenzene sulfonic acid (Ppy-BDSA), as hole injection/transport layers. Although these doped conductive polymers have been shown to increase hole injection fluence and hence PLED device performance, none is ideal because of significant absorption in the visible region and anode interface instability, as exemplified by the ITO/PEDOT-PSS interface. See, M. P. de Jong, L. J. van Ijzendoorn, M. J. A. de Voigt, Appl. Phys. Lett. 2000, 77, 2255-2257; K. W. Wong, H. L. Yip, Y. Luo, K. Y. Wong, W. M. Lau, K. H. Low, H. F. Chow, Z. Q. Gao, W. L. Yeung, C. C. Chang, Appl. Phys. Lett. 2002, 80, 2788-2790.

As a further departure from the prior art, certain embodiments of this invention can comprise or be used in conjunction with high-performance blue polymer light-emitting diodes without use of conventional conductive polymers as hole injection/transport layers. Rather, for example and without limitation, an ultra-thin self-assembled monolayer of the siloxane-derivatized, hole-transporting material 4,4′-bis[p-trichlorosilylpropylphenyl)phenylamino]biphenyl (TPD-Si₂, as above; FIG. 16A and elsewhere) can be used to modify an ITO anode surface, with blue PLED devices then fabricated using the archetypical poly(9,9-dioctylfluorene) (PFO; FIG. 16B) as the emissive layer. As demonstrated herein, modifying an ITO anode with TPD-Si₂ or analogous self-assembled molecular (SAM) layers dramatically increases the performance of the PFO-based blue PLED device: the maximum luminance and current efficiency reach 7,000 cd/m² and 1.1 cd/A, respectively, which is two orders of magnitude greater than a bare ITO-based device. More importantly, the performance of a SAM modified single-layer PLED devices is comparable to or exceeds that of conventional double-layer PLED devices fabricated with PEDOT-PSS as the HTL. As such, the present invention provides a new approach to fabricating high-performance PLEDs—whether emitting blue light or at other wavelengths across the spectrum—without the size and structural requirements of the prior art.

In a broader context, the present invention contemplates a method of using an amine molecular component to enhance hole injection across the electrode-organic interface of a light emitting diode device. Such a method comprises (1) providing an anode and a light-emitting emissive layer; and (2) incorporating a conductive medium adjacent the anode between the anode and the emissive layer, the medium including but not limited to a molecular layer, coupled to the anode, of amine molecular components substituted with at least one silyl group. The molecular layer can comprise at least one of an arylamine component and an arylalkylamine component, including but not limited to those monoarylamine, diarylamine and triarylamine components described in the aforementioned and incorporated U.S. Pat. No. 5,409,783, modified and/or silyl-functionalized as provided herein. Other suitable arylamine and/or arylalkylamine structures are disclosed in U.S. Pat. Nos. 3,180,730, 3,567,450 and 3,658,520, each of which is incorporated herein in its entirety, such structures as can also be modified to provide silyl-functionality in accordance herewith. Likewise, a combination of such silyl-substituted components can be employed with beneficial effect. As mentioned above, device performance and/or light emission can be enhanced without use of a polymeric hole transport layer.

In certain embodiments of this inventive method, the aforementioned amine molecular layer components are alkylsilyl-substituted compounds of the type illustrated in FIGS. 2A and 2C. In certain other embodiments, such components include the alkylsilyl-substituted TAA and alkylsilyl substituted TPD (e.g., TPD-Si₂) compounds, as well as analogous compounds having similar or comparable effect, prepared as described herein. Regardless, such a molecular layer can be spin-coated on the anode surface or self-assembled, as described more fully above, to provide silicon-oxygen bonds therewith. A single such layer of molecular components can be used to reduce device nanodimension. Alternatively, a plurality of such molecular layers can be coupled successively on an anode surface—each layer coupled one to another with silicon-oxygen bonds—to improve structural stability and enhance device performance.

As described herein and with reference to several of the following examples, hole injection and device performance can be enhanced by choice of a molecular layer and/or components thereof having a structural relationship with a conductive layer tending to reduce surface energy mismatch with the anode. A mismatch in surface energy between the LED anode and an associated conductive layer can be understood in terms of the difference between their ionization potentials and illustrated by comparison of respective aqueous contact angle data. (For instance, see examples 12 and 27-28, and FIG. 19.) Incorporation of an amine molecular layer, in accordance with this invention, reduces interfacial surface energy mismatch. In some embodiments, resulting performance enhancement can be achieved through use of a silyl-functionalized TPD layer in conjunction with an emissive layer, although other amine molecular components and emissive layers can be used consistent with the structural and functional relationships described herein.

Improved luminance and efficiency is demonstrated using PFO, representative of a known range of blue light-emitting polymers. Comparable effects are available through use of various other known polymers, capable of emitting light at corresponding wavelengths across the spectrum. Likewise, as shown in several of the following examples, reduction of surface energy mismatch can also be achieved with respect to those embodiments incorporating a hole transport layer, such reduction as can be ascertained via increased maximum luminance and/or quantum efficiency.

As such, in certain embodiments the present invention also includes an organic electroluminescent device for generating light upon application of an electrical potential across two electrodes. Such a device comprises (1) an anode; (2) at least one molecular layer, coupled to the anode, of one or more of the aforementioned amine molecular components substituted with at least one silyl group; (3) a light emissive layer; and (4) a cathode in electrical contact with the anode. An emissive layer comprising PFO can be used with good effect, but devices of this invention can also comprise other emissive layers or components of the prior art as described above and/or incorporated herein by reference. Amine molecular layer components can comprise alkylsilyl-substituted compounds of the type illustrated in FIGS. 2A and 2C, in particular silyl-functionalized TAA and TPD. With consideration of the aforementioned structural/functional relationships and associated methodologies, choice of such molecular layer and emissive layer components is limited only by desired light emission and overall device performance.

As discussed above, device structures having enhanced light emission—at blue wavelengths, in particular—can be fabricated without a polymeric HTL. In such embodiments, taking advantage of the reactive hydroxyl groups on an ITO or related surface, a monolayer of silyl-functionalized TPD-like hole transport material, TPD-Si₂, can be hydrolytically self-assembled onto the anode via colvalent In—O—Si/Sn—O—Si linkages. The resultant smooth, contiguous, and conformal TPD-Si₂ monolayer consists of a siloxane network with embedded, electroactive tetraaryldiamine hole-transporting units. The structures of a TPD-Si₂ precursor molecule and the crosslinked TPD-Si₂ monolayer are illustrated in FIG. 16A. The TPD-Si₂ SAM has been characterized by specular X-ray reflectivity (thickness ˜1.8 nm) and AFM (RMS roughness ˜2.8 nm on ITO of RMS roughness ˜2.4 nm). That TPD-Si₂ SAM coverage on ITO is conformal and largely pinhole-free as well as electroactive is supported by cyclic voltammetry studies using a standard ferrocene probe technique as described herein and elsewhere in the art.

Demonstrating various aspects of this invention, PLED devices with the structure ITO/TPD-Si₂ SAM/PFO/Au/Al were fabricated under inert atmosphere and characterized using the procedures and instrumentation, as described below. For comparison, PLEDs having bare cleaned ITO and ITO/PEDOT-PSS as anodes were also fabricated. The electroluminescence (EL) spectra of all these PLED devices are virtually indistinguishable and consistent with the photoluminescence characteristics of PFO reported previously (FIG. 16B). The device characteristics of the present PLED devices are compared in FIGS. 17A-C, for current-voltage (I-V), luminance-voltage (L-V), and current efficiency-voltage response, respectively. It can be clearly seen that by modifying an ITO anode with the ultra-thin TPD-Si₂ SAM, the PFO-based PLED exhibits a dramatic increase in charge carrier injection, brightness, and current efficiency; the SAM-modified device turns on at 5.5 V and reaches maximum luminance of about 7,000 cd/m² at ˜15 V, and with a current efficiency of 1.1 cd/A. These values of maximum luminance and current efficiency are about two orders of magnitude greater than those of the bare ITO device (the bare ITO based device turns on at ˜12 V and reaches maximum luminance of about 160 cd/m² at about 21 V, and with a current efficiency of 0.03 cd/A).

It is believed this invention represents the first high-performance blue PLED device fabricated without a conventional HTL. Compared with the double-layer PLED control device having PEDOT-PSS as the HTL, the present SAM-modified device exhibits higher maximum current efficiency and three times higher maximum light output, albeit at a somewhat higher turn-on voltage. Compared to previously reported PFO-based PLEDs, the maximum luminance and current efficiency of the present TPD-Si₂ modified device are also significantly higher than those reported for a double-layer device with a poly-arylamine HTL (600 cd/m², 0.25 cd/A). In accordance with this invention, comparable results can be realized using other polymers emitting in other spectral regions.

Other factors can contribute to the benefits available through use of the present invention, irrespective of the emissive layer employed. As illustrated by the TPD-Si₂ SAM-modified PLED devices, an amine molecular layer, as described herein, has negligible visible region absorption. By comparison, PEDOT-PSS has significant absorption, as do other doped conductive polymers such as PANI-CSA, Ppy-BDSA, etc. Likewise, introduction of a PEDOT-PSS HTL significantly increases the thickness of the PLED device—on the order of tens of nanometers—thereby increasing the intrinsic device operating voltage. PEDOT-PSS solutions are also acidic and known to degrade ITO anodes during spincasting—increasing In diffusion into the polymer, compromising hole transfer and reducing current efficiency.

EXAMPLES OF THE INVENTION

The following non-limiting examples and data illustrate various aspects and features relating to the articles/devices and/or methods of the present invention, including the assembly of a luminescent medium having various molecular components/agents and/or conductive layers, as are available through the synthetic methodology described herein. In comparison with the prior art, the present methods and articles/devices provide results and data which are surprising, unexpected and contrary to the prior art. While the utility of this invention is illustrated through the use of several articles/devices and molecular components/agents/layers which can be used therewith, it will be understood by those skilled in the art that comparable results are obtainable with various other articles/devices and components/agents/layers, as are commensurate with the scope of this invention.

Example 1

Synthesis of a Silanated Hole Transport Agent [1]. With reference to reaction scheme, above, hole transport components, agents and/or layers can be prepared, in accordance with this invention and/or for use in conjunction with light-emitting diodes and other similar electroluminescent devices. Accordingly, 500 mg. (1.0 mmole) of trisbromophenylamine (Aldrich Chemical Company) was dissolved in 30 ml of dry dimethoxyethane (DME). This solution was cooled to 45° C. and 1.2 ml (3.3 mmole) of a 2.5 M solution of n-butyl lithium in hexane was added to the reaction mixture. The entire mixture was then slowly warmed to 20° C. After stirring at 20° C. for an additional hour, the solvent was removed in vacuo. The resulting white precipitate was washed (3×20 ml) with dry pentane and redissolved in 30 ml dry DME. This solution was subsequently poured into 10 ml (87 mmole) of silicon tetrachloride at a rate of 1 ml/min. The entire reaction mixture was then refluxed for two hours. The resulting supernatent was separated from the precipitate, and the solvent again removed in vacuo yielding a green-brown residue. A white solid was obtained from this residue upon sublimation at 10⁻⁶ torr. Characterization: ¹H NMR (600 MHz, C₆D₆, 20° C.): δ7.07 (d, 6H, Ar—H); δ7.05 (d, 6H, Ar—H); EI-MS (m/z): 645 (M+).

Example 2

With reference to FIGS. 2A-2C and the representative arylamines provided therein, other hole transport agents and/or layers of this invention can be obtained by straightforward application of the silanation procedure described above in Example 1, with routine synthetic modification(s) and optimization of reaction conditions as would be well-known to those skilled in the art and as required by the particular arylamine. Likewise, preliminary halogenation/bromination can be effected using known synthetic procedures. Alternatively, the arylamines of FIGS. 2A-2C and other suitable substrates can be prepared using other available synthetic procedures to provide multiple silane reaction centers for use with the self-assembly methods and light-emitting diodes of this invention. Core molecular substrates of the type from which the arylamines of FIGS. 2A-2C can be prepared are described by Strukelji et al. in Science, 267, 1969 (1995), which is incorporated herein by reference in its entirety.

Example 3

Synthesis of a Silanated Electron Transport Agent. With reference to Examples 3(a)-(d) and corresponding reaction schemes, below, electron transport agents and/or layers can be prepared, in accordance with this invention and/or for use in conjunction with light-emitting diodes and other similar electroluminescent devices.

Example 3a

Synthesis of 4′-Bromo-2-(4-bromobenzoyl)acetophenone [2]. In a 1-liter three neck round bottom flask, 43 g (0.2 mol) methyl 4-bromobenzoic acid and 17.6 g (0.4 mol) sodium hydride were dissolved in 200 ml dried benzene and heated to 60° C. Next, 39.8 g (0.2 mol) 4-bromoacetophenone in 100 ml dry benzene was slowly added through a dropping funnel, and 1 ml methanol was added to the flask to initiate the reaction. After the mixture was refluxed overnight, the reaction was quenched by adding methanol and pouring it into ice water. The pH of the mixture was brought down to 7.0 using 5 N sulfuric acid. A solid was collected, washed with water, and recrystallized from benzene to give a light yellow product. Characterization. Yield: 30.3 g (40%). ¹H NMR (300 MHz, CDCl₃, 20° C., δ): 7.84 (d, 4H, ArH); 7.62 (d, 4H, ArH); 6.77(s, 2H, CH2). EI-MS: 382(M+), 301, 225, 183, 157.

Example 3b

Synthesis of 3,5-Bis(4-bromophenyl)isoxazole [3]. In a 250 ml round bottom flask, 4 g (10.4 mmol) of [2] was dissolved in 100 ml dry dioxane and heated to reflux, then 3.0 g (43.2 mmol) hydroxylamine hydrogen chloride in 10 ml water and 5 ml (25 mmol) 5 N NaOH was then dropped into the refluxing mixture. After 12 hours, the reaction mixture was cooled down to room temperature, and the solvent was removed in vacuo. The product was recrystallized from ethanol. Characterization. Yield: 3.41 g (85%). M.P. 218.5-219.5° C. ¹H NMR (300 MFz, CDCl₃, 20° C., δ): 7.78(d, 2H, ArH), 7.74 (d, 2H, Ar′H), 7.66 (d, 2H, ArH), 7.62 (d, 2H, Ar′H), 6.82 (s, 1H, isoxazole proton). EI-MS: 379(M+), 224, 183, 155.

Example 3c

Synthesis of 3,5-Bis(4-allylphenyl)isoxazole [4]. In a 250 ml three-neck round bottom flask, 3.77 g (10 mmol) of [3], 460 mg. (0.4 mmol) tetrakis-(triphenylphosphine) palladium, and 7.28 g (22 mmol) tributylallyltin were dissolved in 100 ml. dried toluene and degassed with nitrogen for 30 min. The mixture was heated to 100° C. for 10 h, then cooled down to room temperature. Next, 50 ml. of a saturated aqueous ammonium fluoride solution was subsequently added to the mixture. The mixture was extracted with ether, and the combined organic layer was washed by water, then brine, and finally dried over sodium sulfate. The solvent was removed in vacuo. The residue was purified by column chromatography. (first, 100% hexanes, then chloroform:hexanes [80:20]). Characterization. Yield: 1.55 g (57%). ¹H NMR (300 MHz, CDCl₃, 20° C., δ): 7.78(d, 2H, ArH), 7.74 (d, 2H, Ar′H), 7.34 (d, 2H, ArH), 7.30 (d, 2H, Ar′H), 6.78 (s, 1H, isoxazole proton), 5.96 (m, 2H, alkene H), 5.14 (d, 4H, terminal alkene H), 3.44 (d, 4H, methylene group). EI-MS: 299(M+), 258, 217.

Example 3d

Synthesis of 3,5-Bis(4-(N-trichlorosllyl)propylphenyl)isoxazole [5]. To 2 ml of THF was added 5 mg of [4], 3.4 μl of HSiCl₃ and 0.8 mg. of H₂PtCl₆ were added to 2 ml of THF. The reaction was heated at 50° C. for 14 h. The solvent was then removed in vacuo. A white solid was obtained from this residue upon sublimation at 10⁻⁶ torr. Characterization. ¹H NMR (300 MHz, d⁸-THF, 20° C., δ): 7.72(d, 2H, ArH), 7.68 (d, 2H, Ar′H), 7.36 (d, 2H, ArH), 7.32 (d, 2H, Ar′H), 6.30(s, 1H, isoxazole); 2.52(t, 2H, CH); 1.55 (m, 4H, CH₂); 0.85 (t, 6H, CH₃).

Example 4

With reference to FIGS. 4A-4C and the representative heterocycles provided therein, other electron transport agents and/or layers of this invention can be obtained by straight-forward application of the silanation procedure described above in Example 3, with routine synthetic modification(s) and optimization of reaction conditions as would be well-known to those skilled in the art and as required by the particular heterocyclic substrate. Preliminary halogenation/bromination can be effected using known synthetic procedures or through choice of starting materials enroute to a given heterocycle. Alternatively, the heterocycles of FIGS. 4A-4C and other suitable substrates can be prepared using other available synthetic procedures to provide multiple silane reaction centers for use with the self-assembly methods and light-emitting diodes of this invention. Core molecular substrates of the type from which the heterocycles of FIGS. 4A-4C can be prepared are also described by Strukeli et al. in Science, 267, 1969 (1995).

Example 5

With reference to FIGS. 3A-3C and the representative chromophores provided therein, erissive agents and/or layers, in accordance with this invention, can be obtained by appropriate choice of starting materials and using halogenation and silanation procedures of the type described in Examples 1-4, above. Alternatively, other chromophores can be silanated using other available synthetic procedures to provide multiple silane reaction centers for use with the self-assembly methods and light-emitting diodes of this invention. Regardless, in accordance with this invention, such emissive agents or chromophores can be used for emission of light at wavelengths heretofore unpractical or unavailable. Likewise, the present invention allows for the use of multiple agents or chromophores and construction of an emissive layer or layers such that a combination of wavelengths and/or white light can be emitted.

Example 6

Examples 6(a)-6(c) together with FIG. 6 illustrate the preparation of other molecular components which can be used in accordance with this invention.

Example 6a

Synthesis of Tertiary Arylamine [6]. Together, 14.46 g (20 mmole) of tris(4-bromophenyl)amine and 500 ml of dry diethyl ether were stirred at −78° C. under a nitrogen atmosphere. Next, 112.5 ml of a 1.6 M n-butyllithium solution in hexanes was slowly added to the reaction mixture over 1.5 hours. The reaction was then warmed to −10° C. and stirred for an additional 30 minutes. The reaction was then cooled down again to −78° C. before the addition of 22 g (0.5 mole) of ethylene oxide. The mixture was stirred and slowly warmed to room temperature over 12 hours. Next, 2 ml of a dilute NH₄Cl solution was then added to the reaction mixture. The solvent was evaporated under vacuum yielding a light green solid. The product was purified using column chromatography. The column was first eluted with chloroform and then with MeOH:CH₂Cl₂ (5:95 v/v). The resulting light gray solid was recrystallized using chloroform to give 1.89 g. Yield: 25%. ¹H NMR (δ, 20° C., DMSO): 2.65 (t,6H), 3.57 (q,6H), 4.64 (t,3H), 6.45 (d,6H), 7.09 (d,6H). EI-MS: 377 (M⁺), 346 (M⁺−31), 315 (M⁺−62). HRMS: 377.2002. calcd; 377.1991. Anal. Calculated for C₂₄H₂₇NO₃; C, 76.36; H, 7.21; N, 3.71. Found: C, 76.55; H, 7.01; N, 3.52.

Example 6b

Synthesis of Tosylated Arylamine [7]. A pyridine solution of tosyl chloride (380 mg in 5 ml) was added over 5 minutes to a pyridine solution of [6] (500 mg in 10 ml, from Example 6a) cooled to 0° C. The mixture was stirred for 12 hours, then quenched with water and extracted with chloroform. The organic extract was washed with water, 5% sodium bicarbonate, and dried with magnesium sulfate. After filtration, the chloroform solution was then evaporated to dryness under vacuum and purified using column chromatography. The column was first eluted with hexane:CHCl₃ (1:2 v/v) yielding [7]. ¹H NMR (300 MHz, δ, 20° C., CDCl₃): 2.45 (s,3H), 2.90 (t,6H), 3.02 (t,3H), 3.70 (t,3H), 4.19 (t,6H), 6.92 (d,2H), 6.98 (d,4H), 7.00 (d,4H), 711 (d,2H), 7.32 (d,2H), 7.77 (d,2H).

Example 6c

Synthesis of Tosylated Arylamine [8]. Continuing the chromatographic procedure similar for 2 (from Example 6b)but changing the eluting solvent to 100% CHCl₃ yielded [8]. ¹H NMR (300 MHz, δ, 20° C., CDCl₃): 2.44 (s,6H), 2.91 (t,3H), 3.02 (t,6H), 3.70 (t,6H), 4.19 (t,3H), 6.92 (d,4H), 6.98 (d,2H), 7.00 (d,2H), 7.11 (d,4H), 7.32 (d,4H), 7.77 (d,4H).

Example 7

Using the arylamines of Examples 6 and with reference to FIG. 7, an electroluminescent article/device also in accordance with this invention is prepared as described, below. It is understood that the arylamine component can undergo another or a series of reactions with a silicon/silane moiety of another molecular component/agent to provide a siloxane bond sequence between components, agents and/or conductive layers. Similar electroluminescent articles/devices and conductive layers/media can be prepared utilizing the various other molecular components/agents and/or layers described above, such as in Examples 1-5 and FIGS. 1-4, in conjunction with the synthetic modifications of this invention and as required to provide the components with the appropriate reactivity and functionality necessary for the assembly method(s) described herein.

Example 7a

This example of the invention shows how slides can be prepared/cleaned prior to use as or with electrode materials. An indium-tin-oxide (ITO)-coated soda lime glass (Delta Technologies) was boiled in a 20% aqueous solution of ethanolamine for 5 minutes, rinsed with copious amounts of distilled water and dried for 1 hour at 120° C.; alternatively and with equal effect, an ITO-coated soda lime glass (Delta Technologies) was sonicated in 0.5M KOH for 20 minutes, rinsed with copious amounts of distilled water and then ethanol, and dried for 1 hour at 120° C.

Example 7b

Electroluminescent Article Fabrication and Use. The freshly cleaned ITO-coated slides were placed in a 1% aqueous solution of 3-aminopropyltrimethoxysilane and then agitated for 5 minutes. These coated slides were then rinsed with distilled water and cured for 1 hour at 120° C. The slides were subsequently placed in a 1% toluene solution of [7] (or [8] from Example 6) and stirred for 18 hours under ambient conditions. Afterwards, the slides were washed with toluene and cured for 15 minutes at 120° C. AlQ₃ (or GaQ₃; Q=quinoxalate) was vapor deposited on top of the amine-coated slides. Finally, 750-1000 Å of aluminum was vapor deposited over the metal quinolate layer. Wires were attached to the Al and ITO layers using silver conducting epoxy (CircuitWorks™), and when a potential (<7V) was applied, red, orange, and/or green light was emitted from the device.

Example 8

One or more capping layers comprising Cl₃SiOSiCl₂OSiCl₃ are successively deposited onto clean ITO-coated glass where hydrolysis of the deposited material followed by thermal curing/crosslinking in air at 125° C. yields a thin (˜7.8 Å) layer of material on the ITO surface. X-ray reflectivity measurements indicate that the total film thickness increases linearly with repeated layer deposition, as seen in FIG. 8. Other molecular components can be used with similar effect. Such components include, without limitation, the bifunctional silicon compounds described in U.S. Pat. No. 5,156,918, at column 7 and elsewhere therein, incorporated by reference herein in its entirety. Other useful components, in accordance with this invention include those trifuctional compounds which cross-link upon curing. As would be well known to those skilled in the art and made aware of this invention, such components include those compounds chemically reactive with both the electrode capped and an adjacent conductive layer.

Example 9

Cyclic voltametry measurements shown in FIG. 9 using aqueous ferri/ferrocyanide show that there is considerable blocking of the electrode after the deposition of just one layer of the self-assembled capping material specified in Example 8. Other molecular components described, above, show similar utility. Almost complete blocking, as manifested by the absence of pinholes, is observed after application of three layers of capping material.

Example 10

Conventional organic electroluminescent devices consisting of TPD (600 Å)/Alq (600 Å)/Mg (2000 Å) were vapor-deposited on ITO substrates modified with the capping material specified in Example 8. FIGS. 10A-C show the behavior of these devices with varying thickness of the self-assembled capping material. These results show that such a material can be used to modify forward light output and device quantum efficiency. For a device with two capping layers, higher current densities and increased forward light output are achieved at lower voltages, suggesting an optimum thickness of capping material can be used to maximize performance of an electroluminescent article.

Example 11

This example illustrates how a capping material can be introduced to and/or used in the construction of an electroluminescent article. ITO-coated glass substrates were cleaned by sonication in acetone for 1 hour followed by sonication in methanol for 1 hour. The dried substrates were then reactively ion etched in an oxygen plasma for 30 seconds. Cleaned substrates were placed in a reaction vessel and purged with nitrogen. A suitable silane, for instance a 24 mM solution of octachlorotrisiloxane in heptane, was added to the reaction vessel in a quantity sufficient to totally immerse the substrates. (Other such compounds include those described in Example 8). Substrates were allowed to soak in the solution under nitrogen for 30 minutes. Following removal of the siloxane solution the substrates were washed and sonicated in freshly distilled pentane followed by a second pentane wash under nitrogen. Substrates were then removed from the reaction vessel washed and sonicated in acetone. Substrates were dried in air at 125° C. for 15 minutes. This process can be repeated to form a capping layer of precisely controlled thickness.

Example 12

The stability of device-type TPD-Si₂ molecular layer/TPD hole transport layer interfaces under thermal stress (one measure of durability) was investigated by annealing ITO/TPD-Si₂ (40 nm)/TPD (100 nm) bilayers at 80° C. for 1.0 h. The optical image of the annealed TPD film shows no evidence of TPD de-wetting/decohesion (FIG. 12A), indicating that the ITO-TPD surface energy mismatch is effectively moderated by the interfacial TPD-Si₂ molecular layer. In contrast, the bare ITO/TPD interface exhibits catastrophic de-wetting/de-cohesion under identical thermal cycling (FIG. 12B), visible even under a layer of Alq). Despite seemingly similar cohesive effects for both TAA and TPD-Si₂ as interfacial buffer layers, it is reasonable to suggest that the interfacial cohesion between TPD-Si₂ and TPD is greater, given closer structural similarity, evidenced by comparing advancing aqueous contact angles: values for bare ITO, silyl-functionalized TAA, silyl (Si₂) functionalized TPD and TPD film surfaces are 0°, 45°, 70°, and 85° respectively, indicating a closer surface energy match at TPD-TPD-Si₂ interfaces.

Example 13

Speculation that one role of Cu(Pc) in enhancing OLED performance might be via the above adhesion mechanism led to parallel thermal studies. In contrast to a preferred alkylsilyl-substituted arylamine TPD-Si₂, Cu(Pc)-buffered ITO does not prevent TPD de-cohesion upon heating to temperatures near/above the TPD glass transition temperature (T_(g)). FIG. 12D illustrates the morphology of a 100 mn TPD film on 10 nm Cu(Pc) following heating at 80° C. It is clearly seen that thermal annealing induces TPD crystallization on the Cu(Pc) film surface (visible even under a layer of Alq), yielding star-shaped dendritic crystallites (as-deposited TPD films on Cu(Pc) are smooth and featureless, FIG. 12C). It is likely that such Cu(Pc)-nucleated crystallization occurs during localized heating in operating OLEDs and contributes to observed device instability.

Example 14

Device characteristics employing spincoated TAA, TPD-Si₂, and vapor-deposited Cu(Pc) hole injection layer/adhesion layers in OLEDs having the structure ITO/interlayer/TPD/Alq/Al are compared in FIG. 13. Versus the bare ITO system, all of the molecular/buffer layer-incorporated devices exhibit higher light output, enhanced quantum efficiencies, and lower turn-on voltages. Note that a preferred TPD-Si₂ component layer affords ˜15,000 cd/m² of maximum light output, which is 10-100× greater than the bare ITO-based device. Similar increases in ITO/TPD/Alq/Al-type device performance with electrode functionalization have only been reported previously for LiF or CsF-modified Al cathodes, via what remains an unresolved mechanism. It is widely accepted that conventional ITO/ID/Alq/Al heterostructures are electron-limited due to the low Alq electron mobility and Alq LUMO-Al Fermi level energetic mismatch, thus raising the question of why TPD-Si₂ anode modification produces similar effects. It is suggested that under conditions of anode-HTL surface energy mismatch and poor anode-HTL cohesion (an unmodified device of prior art), non-ohmic contacts dominate device behavior, resulting in significant hole injection barriers typical of poor electrode-organic contact.

Example 15

With reference to FIG. 14, TAA and TPD-Si₂ interfacial/molecular component layers are significantly more effective injection structures than conventional Cu(Pc) layers. The maximum light output for a Cu(Pc)-based device is 1500 cd/m² at 25 V, while that of a TAA-based device is 2600 cd/m², and at a much lower bias voltage (16 V). The external quantum efficiency of the Cu(Pc)-based device also falls well below those based on TAA and TPD-Si₂ anode layers: the maximum quantum efficiency for Cu(Pc) is 0.3 %, in contrast to those of TPD-Si₂ (˜1.2%) and TAA (˜0.9%). The TPD-Si₂-functionalized device is most efficient, producing a maximum light output ˜10× greater than the Cu(Pc)-buffered device, and ˜100× greater than the bare ITO-based device. Improvements observed and differences between TPD-Si₂ and silyl-functionalized TAA molecular layers can be explained, without limitation, in relation to: (1) closer aromatic structural similarity of TPD-Si₂ to TPD, producing a stronger interlayer affinity and presumably greater π-π interfacial overlap, and (2) the higher triarylamine: siloxane linker ratio in TPD-Si₂, consistent with more facile hole hopping via denser triarylamine packing.

Example 16

These findings argue that promotion of ITO-TPD interfacial contact/adhesion leads to more efficient hole injection due to reduced interfacial contact resistance. This hypothesis was tested by examining characteristics of hole-only devices having the structure ITO/molecular interlayer/TPD(250 nm)/Au(6 nm)/Al(80 nm), in which electron injection at the cathode is blocked. Here the Au layer is deposited by rf-sputtering to avoid excessive heating of the TPD underlayer. The hole injection capacity falls in the order TPD-Si₂≧TAA>Cu(Pc)>bare ITO (FIG. 14). Compared to bare ITO, the silyl-functionalized TAA- and TPD-Si₂-modified anodes enhance the hole current density by 10-100× for the same field strength, with ITO/TPD-Si₂ being most effective. Thus, when contact resistance at the OLED anode side is reduced and hole injection increased, the greater electric field induced across the Alq layer enhances electron injection and transport, affording higher light output and comparable or, in the cases where recombination is more probable, enhanced quantum efficiency. In contrast, the present and related data for Cu(Pc) devices show that the Cu(Pc) significantly suppresses hole injection. E. W. Forsythe, M. A. Abkowitz, Y. Gao, J. Phys. Chem. B 2000, 104, 3948; S. C. Kim, G. B. Lee, M. Choi, Y. Roh, C. N. Whang, K. Jeong, Appl. Phys. Lett. 2001, 78, 1445. It is believed, in light of these results, that Cu(Pc) enhances quantum efficiency via better balancing hole and electron injection fluences, rather than by facilitating hole injection or interfacial stability.

Example 17

To examine cohesion and crystallization effects on device durability, thermal stress tests were carried out on devices based on bare ITO, having a 10 nm Cu(Pc) interlayer, and having a 40 nm TPD-Si₂ interlayer. These were subjected to heating at 95° C. for 0.5 h in vacuum and subsequently examined for changes in luminous response. The irreversible degradation of the bare ITO and Cu(Pc)-based devices upon heating at 95° C. for 0.5 h (FIG. 15) is reasonably ascribed to TPD de-wetting and Cu(Pc)-nucleated TPD crystallization, respectively. Both processes would disrupt the multilayer structure, leading to direct hole injection into, and consequent degradation of, the emissive Alq layer, and possible amplification of pinholes and defects. In contrast, TPD-Si₂-buffered molecular layer devices exhibit enhanced performance after heating, which is presumably a consequence of interfacial reconstruction that promotes charge injection. These experiments unambiguously demonstrate that covalently interlinked alkylsilyl-substituted compounds such as TPD-Si₂ and TAA, when used as described herein, offer significant improvements in stabilizing the anode-HTL interface and promoting hole injection.

The results of this and several preceding examples, demonstrate that a spincoated, hole injecting TPD-Si₂ layer can significantly increase maximum OLED device luminence (˜100×) and quantum efficiency (˜6×) by promoting ITO-TPD interfacial cohesion, hence promoting more efficient hole injection. Devices having a TPD-Si₂ anode adhesion layer afford a maximum luminance level of 15,000 cd/m² in absence of dopants or low work function cathodes, while exhibiting excellent thermal stability. In addition, the same results demonstrate that Cu(Pc) interlayers nucleate TPD crystallization upon heating above the T_(g) of TPD

Example 18

The synthesis of alkylsilyl-functionalized TAA is as was previously described, both herein and in the literature. W. Li, Q. Wang, J. Cui, H. Chou, T. J. Marks, G. E. Jabbour, S. E. Shaheen, B. Kippelen, N. Pegyhambarian, P. Dutta, A. J. Richter, J. Anderson, P. Lee, N. Armstrong, Adv. Mater. 1999, 11, 730. TPD, Alq, and Cu(Pc) were obtained from Aldrich and purified by gradient sublimation. All other reagents were used as received unless otherwise indicated. TPD-Si₂ can be synthesized as provided elsewhere, herein (see Example 2) or according to FIG. 11B and Examples 19-21, and further characterized by ¹H NMR spectroscopy and elemental analysis.

Example 19

With reference to FIG. 11B enroute to TPD-Si₂, the synthesis of 4,4′-bis[(p-bromophenyl)phenylamino)biphenyl (9). To a solution of tris(dibenzyldeneacetone)dipalladium (0.55g, 0.6 mmol), and bis-(diphenylphosphino)ferrocene; (0.50g, 0.9 mmol) in toluene (50 mL), was added 1,4-dibromobenzene (18.9g, 0.0800 mol) at 25° C., and the solution stirred under N₂ for 10 min. Subsequently, sodium tert-butoxide (4.8 g, 0.050 mol) and N,N′-diphenylbenzidine (6.8 g, 0.020 mol) were added, and the reaction mixture stirred at 90° C. for 12 h. The reaction mixture was subsequently cooled to 25° C. and poured into water. The organic layer was separated, and the aqueous layer was extracted with toluene (3×100 mL). The extract was combined with the original organic layer, and the solvent was removed in vacuo to give the crude product. This was purified by chromatography on silica gel using hexane: ethylene chloride (6:1) as the eluant. A white solid (6.9 g) was obtained in 50% yield.¹H NMR (CDCl₃): δ6.99(d, J=8.8 Hz, 4H), 7.02-7.16(m, 10H), 7.28(t, J=7.6 Hz, 4H), 7.34(d, J=8.8 Hz, 4H), 7.45(d, J=8.4 Hz, 4H).

Example 20

With further reference to FIG. 11B enroute to TPD-Si₂, the synthesis of 4,4′-bis[(p-allylphenyl)′phenylamino]biphenyl (10). To a stirring, anhydrous ether solution (10 mL) of 1(1.02 g, 1.58 mmol) under N₂ was added dropwise at 25° C. 1.6 mL (3.5 mmol) n-butyl lithium(2.5 M in hexanes), and the mixture stirred for 2 h. CuI (0.76 g, 4.0 mmol) was then added, the reaction mixture cooled to 0° C., and allyl bromide (0.60 g, 5.0 mmol) added in one portion. The solution was stirred for 14 h, after which time it was quenched with 100 mL saturated aqueous NH₄ ⁺Cl⁻ solution, followed by extraction with ether (3×100 mL). The combined ether extracts were washed with water (2×100 mL) and brine (2×100 mL), and dried over anhydrous Na₂SO₄. Following filtration, solvent was removed in vacuo to yield a yellow oil. Chromatography on silica gel with hexane: ethylene chloride (4:1) afforded 0.63 g white solid. Yield, 70%. ¹H NMR (CDCl₃) δ3.40(d, J=10 Hz, 4H), 5.10-5.20(m, 4H), 6.02(m, 2), 6.99-7.10(m, 2H), 7.10-7.20(m, 16H), 7.28(t, J=7.6 Hz, 4H), 7.46(d, J=8.8 Hz, 4H). Anal. Calcd for C₄₂H₃₆N₂: C 88.68, H 6.39, N 5.23 Found, C 87.50, H 6.35, N 4.93.

Example 21

With reference to FIG. 11B enroute to TPD-Si₂, the synthesis of 4,4′-bis[(p-trichlorosilylpropylphenyl)phenylamino]biphenyl (11). To a solution of 2 (0.32 g, 0.55 mol) in 30 mL CH₂Cl₂ at 25° C. was added a grain of H₂PtCl₆.xH₂O, followed HSiCl₃ (0.73 g, 5.5 mmol). The reaction solution was warmed to 30° C. and stirred for 4 h. Removal of the solvent in vacuum yielded a dark-yellow oil. A mixture of 50 mL pentane and 10 mL toluene was then added. The resulting solid was filtered off, and the filtrate was concentrated under vacuum to a viscous, pale-yellow oil. Yield, 98%. ¹H NMR (CDCl₃): δ1.45(t, J=7 Hz, 4H), 1.90(t, J=7 Hz, 4H), 2.70(brs, 4H), 6.80-7.80(m, 26H). Anal. Calcd for C₄₂H₃₈Cl₆N₂Si₂: C 60.07, H 4.57; Found, C 60.52, H 4.87.

Example 22

With reference to Examples 19-21, a wide variety of arylalkylamine molecular components and their silyl-functionalized analogs can be prepared using straight-forward modifications of the synthetic techniques described herein. For instance, with reference to Example 19, diphenylbenzidene can be mono- or dialkylated with the appropriate haloalkyl reagent to provide the desired arylalkylamine hole transport layer component. As would also be well known to those skilled in the art made aware of this invention, the corresponding silyl-functionalized molecular layer component can be prepared via mono- or dialkylation with the appropriate dihaloalkyl reagent followed by subsequent silation, adopting the procedures illustrated in Examples 20 and 21. Accordingly, by way of further example, the alkylated mono- and diarylamine components, discussed above, and their silyl-functionalized analogs can be prepared to provide the structurally-related molecular and hole transport layers of this invention, and the enhanced performance and/or hole injection resulting therefrom.

Example 23

TPD-Si₂ and TAA Thin Film Deposition and Characterization. Indium tin oxide (ITO) glass sheets with a resistance of 20 Ω/□ from Donnelly Corp. were subjected to a standard literature cleaning procedure. TAA and TPD-Si₂-based buffer layers were spincoated onto cleaned ITO surfaces from their respective toluene solutions (10 mg/mL) at 2 Krpm, followed by curing in moist air at 110° C. for 15 min. Cyclic voltammetry of spincoated TPD-Si₂ films on ITO was performed with a BAS 100 electrochemical workstation (scan rate, 100 mV/s; Ag wire pseudo-reference electrode, Pt wire counter electrode, supporting electrolyte, 0.1 M TBAHFP in anhydrous MeCN). For TPD-Si₂ film contiguity assessment, 1.0 mM ferrocene in 0.1 M TBAHFP/MeCN was used as the probe. Thermogravimetric analysis (TGA) was carried out on an SDT 2960 DTA-TGA instrument with a scan rate of 10° C./min under N₂. TGA sample preparation involved drop-coating a TPD-Si₂ solution in toluene (10 mM) onto clean glass substrates under ambient conditions. Following solvent evaporation, the TPD-Si₂-coated slides were cured at 120° C. for 1 h. Upon cooling, the films were detached from the glass substrates using a razor blade and collected as powders for TGA characterization.

Example 24

ITO/Buffer Layer /TPD Interfacial Stability Studies. TPD de-cohesion analysis of the interfacial structures ITO/buffer layer /TPD (100 nm) (spincoated TPD-Si₂, spincoated TAA, vapor-deposited Cu(Pc)) were carried out in the following manner. Following vapor deposition of 50-100 nm TPD films onto the respective buffer layer-coated ITO substrates, the samples were annealed at 80-100° C. under N₂ for 1.0 h, and the film morphology subsequently imaged by optical microscopy and AFM.

Example 25

OLED Device Fabrication. OLED devices of the structure: ITO/interlayer/TPD(50 nm)/Alq(60 nm)/Al(100 nm) were fabricated using standard vacuum deposition procedures (twin evaporators interfaced to a <1 ppm O₂ glove box facility). Deposition rates for organic and metal were 2-4 Å/sec and 1-2 Å/sec respectively, at 1×10⁻⁶ Torr. The OLED devices were characterized inside a sealed aluminum sample container under N₂ using instrumentation described elsewhere. J. Cui, Q. Huang, Q. Wang, T. J. Marks, Langmuir 2001, 17,2051; W. Li, Q. Wang, J. Cui, H. Chou, T. J. Marks, G. E. Jabbour, S. E. Shaheen, B. Kippelen, N. Pegyhambarian, P. Dutta, A. J. Richter, J. Anderson, P. Lee, N. Armstrong, Adv. Mater. 1999, 11, 730.

Example 26

Device Thermal Stability Evaluations. OLED devices were subjected to heating under vacuum at 95° C. for 0.5 h, and were subsequently evaluated for I-V and L-V characteristics as described above.

Example 27

That hole injection is thought to be a principal factor limiting the performance of single-layer blue PLEDs raises the question of whether enhanced hole injection may have a role in the performance level of the SAM-modified single-layer PLED's of this invention. This hypothesis was further tested by examining characteristics of “hole-only” devices (I. Parker, J. Appl. Phys. 1994, 75, 1656-1666) having the structure ITO/TPD-Si₂ SAM or PEDOT-PSS/PFO/Au/Al, in which electron injection at the cathode is blocked by a gold layer. (See, example 31.) The current-voltage characteristics of relevant hole-only devices are compared in FIG. 18. It can be seen that at typical experimental voltages, the SAM-modified ITO anode enhances the hole injection current by ˜100× vs. bare ITO and 5-10× vs. the PEDOT-PSS modified ITO anode. This dramatic increase in hole injection can be attributed, among other factors, to the higher ionization potential (IP) of the SAM-on ITO as revealed by ultraviolet photoelectron spectroscopy measurements.

The IP of the TPD-Si₂ SAM/ITO is determined to be 5.5 eV, which is 0.8 eV higher than that of the bare ITO anode (4.7 eV) and 0.3 eV higher than that of PEDOT-PSS (5.2 eV; FIG. 19). The IP of TPD-Si₂ SAM/ITO is measured from the high KE edge of the photoelectron spectrum, while HOMO level of TPD-Si₂ is determined from the spectral maximum, and found to be 6.2 eV. That the IP values can be correlated with apparent work functions and intrinsic hole injection barriers can support the position that the present TPD-Si₂ SAM modification moderates the discontinuity in ITO EF-PFO HOMO energy levels, thus reducing the intrinsic hole injection barrier and effectively increasing the hole injection fluence.

Example 28

The enhanced hole injection by TPD-Si₂ SAM modification may also be related to higher interfacial affinity between the SAM-modified ITO and PFO. It is recognized in the art that interfacial properties play a very important role in the response characteristics of organic LEDs. The large surface energy mismatch and consequent poor physical-electronic contact between a hydrophilic ITO and a hydrophobic emissive polymer such as PFO may be another cause of the inefficient hole injection observed. That this surface energy mismatch can be minimized by modifying the ITO anode with the TPD-Si₂ triarylamine SAM is evidenced by advancing aqueous contact angle data. The relevant angles for clear ITO, ITO/PEDOT-PSS, TPD-Si₂-modified ITO, and PFO surfaces are 20°, 30°, 80°, and 90°, respectively.

Example 29

PFO synthesis. The polymer was synthesized from 2,7-dibromo-9,9-dioctylfluorene and 2,7-bis(4,4,5,5-tetramethyl-1,3,2-dioxaborolan-2-yl)-9,9-dioctylfluorene using Suzuki coupling methodology and was carefully purified by repetitive precipitation to remove ionic impurities and catalyst residues. See, N. Miyaura, A. Suzuki, Chem. Rev. 1995, 95, 2457-2483. The number and weight average molecular weights (M_(n) and M_(w)) of PFO were determined to be 54,700 and 107,000 (polydispersity=1.95), respectively, by gel permeation chromatography (GPC) using tetrahydrofuran as solvent and polystyrene as standards. The chemical structure of PFO was verified by NMR and elemental analysis.

Example 30

Self-assembly of TPD-Si₂. TPD-Si₂ was synthesized according to a procedure described herein (examples 19-21) and as reported previously. J. Cui, Q. Huang, J. G. C. Veinot, H. Yan, T. J. Marks, Adv. Mater. 2002, 14, 565. Indium tin oxide (ITO) coated glass with a sheet resistance of 20 Ω/ was used as the substrate for the self-assembly of TPD-Si₂ and PLED fabrication. The substrates were first washed with organic solvents in an ultrasonic bath, then cleaned by oxygen plasma etching. TPD-Si₂ was self-assembled from a hot (90° C.) dry toluene solution onto the aforementioned cleaned ITO substrates by procedures described above (see, examples 23 and 25) and then dried in a vacuum oven before use. Various other amine molecular components (e.g., example 22) of this invention can be self-assembled and/or applied to anode components, analogously.

Example 31

PLED device fabrication. All the substrates (SAM-modified ITO, bare ITO, ITO/PEDOT-PSS) were dried in a vacuum oven at 110° C. overnight before PFO was spincast on top of them from a xylene solution to give an emissive layer of a thickness of 80 nm as measured by step profilemetry. The resultant films were dried in a vacuum oven overnight. Inside an inert atmosphere glove box, Au was thermally evaporated onto the PFO film in a vacuum <10⁻⁶ Torr, using a shadow mask to define the electrode area as 10 mm², and followed by Al deposition as a protection layer. PLED devices were characterized inside a sealed aluminum sample container using instrumentation described elsewhere in the art. Electroluminescence spectra were recorded within 0.5 h after device fabrication. While the fabrication of this example was undertaken in conjunction with the “hole only” tests of example 27, analogous fabrication techniques can be employed to provide other PLED devices, with a range of other emissive or conductive layers, such techniques as would be understood by those skilled in the art made aware of this invention.

Example 32

With reference to several of the preceding examples, descriptions, fabrication techniques and/or aforementioned incorporated references, diodes and related device structures of this invention can be prepared using any combination of the present amine molecular layers and known, available emissive polymers/layers. For instance, in accordance with this invention, any such amine molecular layer can be used in conjunction with any emissive polymer of the type provided in U.S. Pat. No. 6,495,644, the entirety of which is incorporated herein by reference: such emissive polymers, whether fully conjugated or of limited conjugating length, covering the full visible range and extending into the near-IR range, as can be incorporated into the present diodes/devices/structures as also provided therein or known in the art. Other emissive polymers useful in conjunction with the present invention include (see, FIG. 20) but are not limited to poly[(9,9-dihexyl-2,7-fluorene)-alt-co-(2,5-didecyloxyl-1,4-phenylene)] (PDHFDDOP), poly[(9,9-dihexyl-2,7-fluorene) (PDHF), and poly[(9,9-dihexyl-2,7-fluorene)-alt-co-(2,5-dihexyl-1,4- phenylene)] (PDHFDHP), as described in Yu, Wang-Lin; Pei, Jian; Cao, Yong; Huang, Wei. Journal of Applied Physics (2001), 89(4), 2343-2350; poly(phenylenevinylene), as described in Lee, Ji-Hoon; Yu, Han-Sung; Kim, Woohong; Gal, Yeong-Soon; Park, Jun-Hong; Jin, Sung-Ho, Journal of Polymer Science, Part A: Polymer Chemistry (2000), 38(23), 4185-4193; and poly[1,bis(4alkyl-2-thienyl)-2,5-disubstituted phenylene), as described in Pei, Jian; Yu, Wang-Lin; Huang, Wei; Heeger, Alan J, Macromolecules (2000), 33(7), 2462-2471. Each such reference is incorporated by reference, herein, in its entirety. Various other polyfluorene polymers can be utilized, such polymers including but not limited to the yellow light-emitting polymers poly(9,9-dioctylfluorene-co-N-(4-butylphenyl)diphenylamine)(TFB) and poly(9,9-dioctylfluorene-co-benzothiadiazole)(BT), and the red light-emitting poly[{9,9-dihexyl-2,7-bis(1-cyanovinylene)fluorenylene}alt-co-{2,5-bis(N,N′-diphenylamino)-1,4-phenylene}]. Reference is made to FIG. 20 and the structures of such polymeric compounds together with structural variations of each as known in the art and as would be understood to affect the wavelength of emitted light—such variations, polymeric compounds and corresponding emissive layers as are also contemplated within the scope of this invention.

While the principles of this invention have been described in connection with specific embodiments, it should be understood clearly that these descriptions are added only by way of example and are not intended to limit, in any way, the scope of this invention. For instance, the present invention can be applied more specifically to the construction of second-order nonlinear optical materials as have been described in U.S. Pat. No. 5,156,918 which is incorporated herein by reference in its entirety. Likewise, the present invention can be used in conjunction with the preparation of optical waveguides. Another advantages and features will become apparent from the claims hereinafter, with the scope of the claims determined by the reasonable equivalents, as understood by those skilled in the art. 

1. A method of using an amine molecular component to enhance hole injection across the electrode-organic interface of a light emitting diode device, said method comprising: providing an anode; and incorporating an electroluminescent medium adjacent said anode, said medium comprising an amine molecular layer, coupled to said anode, said molecular layer having at the least one of an arylamine molecular component and an arylallylamine molecular component, each said component substituted with at least one silyl group, and on said molecular layer a hole transport layer of molecular components having said amine structure.
 2. The method of claim 1 wherein said molecular layer components are selected from the group consisting of alkylsilyl-substituted compounds of FIGS. 2A and 2C.
 3. The method of claim 2 wherein said molecular layer components are selected from the group consisting of alkylsilyl-substituted TAA and alkylsilyl-substituted TPD.
 4. The method of claim 3 wherein said molecular layer is spin-coated on said anode.
 5. The method of claim 3 wherein said anode is immersed in a solution of said molecular layer components.
 6. The method of claim 1 wherein a plurality of molecular layers are coupled to said anode.
 7. The method of claim 1 wherein said hole transport layer is TPD.
 8. The method of claim 7 wherein said hole transport layer is spin-coated on said anode.
 9. An electroluminescent device for generating light upon application of an electrical potential across two electrodes, said device comprising: an anode; at least one amine molecular layer, coupled to said anode, said molecular layer having at least one of an arylamine molecular component and an arylalkylamine molecular component, each said component substituted with at least one silyl group; a conductive layer of molecular components having said amine structure; and a cathode in electrical contact with said anode layer.
 10. The device of claim 9 wherein said molecular layer components are selected from the group consisting of alkylsilyl-substituted compounds of FIGS. 2A and 2C.
 11. The device of claim 10 wherein said molecular layer components are selected from the group consisting of alkylsilyl-substituted TAA and alkylsilyl-substituted TPD.
 12. The device of claim 11 wherein said conductive layer is a hole transport layer of TPD.
 13. The device of claim 9 wherein a plurality of molecular layers are coupled to said anode.
 14. An electroluminescent device for generating light upon application of an electrical potential across two electrodes, said device comprising: an anode; at least one molecular layer, coupled to said anode, of arylamine molecular components substituted with at least two silyl groups; a hole transport layer of TPD molecular components, said hole transport layer substantially without crystallization upon annealing; and a cathode in electrical contact with said anode.
 15. The device of claim 14 wherein said molecular layer components are selected from the group consisting of alkylsilyl-substituted TAA and alkylsilyl-substituted TPD.
 16. The device of claim 14 wherein a plurality of molecular layers are coupled to said anode.
 17. The device of claim 14 further including an electron transport layer.
 18. An electroluminescent device for generating light upon application of an electrical potential across two electrodes, said device comprising; an anode; at least one molecular layer, coupled to said anode, of alkylsilyl-substituted TPD molecular components; a hole transport layer of TPD molecular components and a cathode in electrical contact with said anode.
 19. The device of claim 18 further including, an electron transport layer.
 20. The device of claim 18 wherein a plurality of molecular layers are coupled to said anode.
 21. A method of using an amine molecular component to enhance hole injection across the electrode-organic interface of a light emitting diode device, said method comprising: providing an anode and a light-emitting emissive layer; and incorporating a conductive medium adjacent said anode, said medium comprising an amine molecular layer, coupled to said anode, said molecular layer having at the least one of an arylamine molecular component and an arylalkylamine molecular component, each said component substituted with at least one silyl group, said method substantially without incorporation of a polymeric hole transport layer.
 22. The method of claim 21 wherein said molecular layer components are selected from the group consisting of alkylsilyl-substituted compounds of FIGS. 2A and 2C.
 23. The method of claim 22 wherein said molecular layer components are selected from the group consisting of alkylsilyl-substituted TAA and alkylsilyl-substituted TPD.
 24. The method of claim 23 wherein said molecular layer is spin-coated on said anode.
 25. The method of claim 23 wherein said anode is immersed in a solution of said molecular layer components.
 26. The method of claim 21 wherein said emissive layer is spin-coated on said anode.
 27. The method of claim 21 wherein said emissive layer comprises a blue light-emitting polymer.
 28. The method of claim 27 wherein said emissive layer comprises poly(9,9-dioctylfluorene).
 29. The method of claim 21 wherein said molecular layer reduces surface energy mismatch between said anode and said emissive layer.
 30. An electroluminescent device for generating light upon application of an electrical potential across two electrodes, said device comprising: an anode; at least one amine molecular layer, coupled to said anode, said molecular layer having at least one of an arylamine molecular component and an arylalkylamine molecular component, each said component substituted with at least one silyl group; a polymeric light-emitting emissive layer; and a cathode in electrical contact with said anode layer.
 31. The device of claim 30 wherein said molecular layer components are selected from the group consisting of alkylsilyl-substituted compounds of FIGS. 2A and 2C.
 32. The device of claim 31 wherein said molecular layer components are selected from the group consisting of alkylsilyl-substituted TAA and alkylsilyl-substituted TPD.
 33. The device of claim 30 wherein said emissive layer comprises a blue light-emitting polymer.
 34. The device of claim 33 wherein said emissive layer comprises poly(9,9-dioctylfluorene).
 35. An electroluminescent device for generating light upon application of an electrical potential across two electrodes, said device comprising: an anode; a polymeric light-emitting emissive layer having a surface energy mismatch with said anode; at least one molecular layer, coupled to said anode, of aylmine molecular components substituted with at least one silyl group, said molecular layer capable of reducing said anode/emissive layer mismatch; and a cathode in electrical contact with said anode.
 36. The device of claim 35 wherein said molecular layer components are selected from the group consisting of alkylsilyl-substituted TAA and alkylsilyl-substituted TPD.
 37. The device of claim 35 wherein said emissive layer comprises a blue light-emitting polymer.
 38. The device of claim 37 wherein said emissive layer comprises poly(9,9-dioctylfluorene).
 39. An electroluminescent device for generating light upon application of an electrical potential across two electrodes, said device comprising; an anode; at least one molecular layer, coupled to said anode, comprising alkylsilyl-substituted TPD molecular components; a blue light-emitting emissive layer comprising poly(9,9-dioctylfluorene); and a cathode in electrical contact with said anode.
 40. The device of claim 39 wherein a plurality of molecular layers are coupled to said anode.
 41. The device of claim 39 further including an electron transport layer.
 42. A method of reducing surface energy mismatch in a light-emitting diode device, said method comprising: providing an anode and a conductive layer thereon, said conductive layer having an ionization potential greater than the ionization potential of said anode; and incorporating a medium adjacent said anode, said medium comprising an amine molecular layer, coupled to said anode, said molecular layer having at least one of an arylamine molecular component and an arylalkylamine molecular component, each said component substituted with at least one silyl group, said molecular layer having an ionization potential greater than said anode ionization potential.
 43. The method of claim 42 wherein said molecular layer components are selected from the group consisting of alkylsilyl-substituted compounds of FIGS. 2A and 2C.
 44. The method of claim 43 wherein said molecular layer components are selected from the group consisting of alkylsilyl-substituted TAA and alkylsilyl-substituted TPD.
 45. The method of claim 42 wherein said conductive layer is selected from the group consisting of a hole transport layer and an emissive layer.
 46. The method of claim 45 wherein said emissive layer comprises poly(9,9-dioctylfluorene). 